CN113517952A

CN113517952A - Method and device for determining time-frequency resources

Info

Publication number: CN113517952A
Application number: CN202110891848.8A
Authority: CN
Inventors: 张晨晨; 郝鹏
Original assignee: ZTE Corp
Current assignee: ZTE Corp
Priority date: 2017-09-30
Filing date: 2017-09-30
Publication date: 2021-10-19
Also published as: ES2963688T3; KR102466577B1; EP3691376B1; US11646821B2; EP3691376A1; JP2021500779A; FI3691376T3; US11212038B2; US20220368459A1; WO2019062524A1; JP7090698B2; US20230388050A1; HUE063781T2; US20210050944A1; EP4254851A2; EP3691376A4; KR20200054312A; CN109600844A; CN109600844B; EP4254851A3

Abstract

The invention provides a method and a device for determining time-frequency resources, wherein the method comprises the following steps: the first communication node determines at least one of the following information about the first set of resources: the time-frequency resources of the second resource set, the configuration information of the second resource set and the time-frequency resource configuration information of the first resource set, which are contained in the first resource set, are used for indicating whether the first resource set is multiplexed for PDSCH transmission or PUSCH transmission or not, or whether the dynamic signaling indication of performing rate matching for PDSCH transmission or PUSCH transmission is needed or not; after the information is determined, the information is transmitted to the second communication node, so that the problem of how to indicate the time-frequency resources used by the PDSCH or PUSCH transmission in the related technology is solved, and the time-frequency resources used when the PDSCH or PUSCH transmission is indicated to a user are realized.

Description

Method and device for determining time-frequency resources

The application is a divisional application of Chinese patent applications with the application number of '201710940914. X', the application date of '9 and 30 months in 2017', and the title of 'method and device for determining time-frequency resources'.

Technical Field

The invention relates to the field of communication, in particular to a method and a device for determining time-frequency resources.

Background

In the related art, in a New Radio (NR) system, it is currently determined that a base station may semi-statically configure Resource sets, resources on the Resource sets may be dynamically multiplexed to a Physical Downlink Shared Channel (PDSCH) for transmission, and dynamic signaling is used to indicate which resources of the Resource sets may be multiplexed to a PDSCH for transmission.

In the related art, a Physical Downlink Control Channel (PDCCH for short) of an LTE system maps a Frequency domain in a full bandwidth, and a PCFICH Channel indicates that the PDCCH Channel occupies several Orthogonal Frequency Division Multiplexing (OFDM) symbols in a time domain, so that the PDCCH domain is in the full bandwidth of the Frequency domain, the time domain occupies a structure of several OFDM symbols before one subframe, time-Frequency resources of the PDCCH domain and a PDSCH domain are completely isolated, and resources in the PDCCH domain cannot be used for PDSCH transmission.

In LTE ePDCCH (enhanced PDCCH), ePDCCH is transmitted on (Physical Resource Block, PRB) PRB Set, that is, ePDCCH and PDSCH adopt a frequency division multiplexing mode, and there is no Resource used for ePDCCH transmission in PRB Set, and they can still be used for PDSCH transmission, and a "Resource Block assignment" field in DCI may contain an indication of this part of Resource, so that a terminal can know all Resource allocations used for PDSCH transmission.

For the NR PDCCH, based on several discussions of the 3GPP RAN1 conference at present, the NR PDCCH is designed based on a Control Resource Set (referred to as "CORESET"), which is different from the full bandwidth distribution in the LTE PDCCH, the downlink Control channel distribution in NR is limited by CORESET(s) configured by the system, the CORESET is configured semi-statically, and the user scheduling itself is dynamically changed, so that when there are remaining idle resources in the CORESET, in order to avoid Resource waste, these resources may be used for PDSCH transmission, and how to indicate multiplexed CORESET resources to the user, so that the user knows that there is PDSCH service on these Control resources, which is a problem to be solved.

Further, the 3GPP RAN1 conference configures a semi-static number of Resource sets by the base station, and dynamically indicates whether resources on part of the Resource sets can be multiplexed by scheduled PDSCH transmission, or whether scheduled PDSCH transmission needs to rate match to part of the Resource set resources.

For the problem of how to indicate the time-frequency resources used by the PDSCH transmission in the related art, no effective solution exists at present.

Disclosure of Invention

The embodiment of the invention provides a method and a device for determining time-frequency resources, which are used for at least solving the problem of how to indicate the time-frequency resources used by PDSCH transmission in the related technology.

According to an embodiment of the present invention, a method for determining time-frequency resources is provided, including: the first communication node determines at least one of the following information about the first set of resources for the second communication node: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed to Physical Downlink Shared Channel (PDSCH) or Physical Uplink Shared Channel (PUSCH) transmission, or whether dynamic signaling indication for performing rate matching is required to perform PDSCH or PUSCH transmission; transmitting the information to the second communication node, wherein the PDSCH transmission comprises a process in which the first communication node transmits data to the second communication node over a PDSCH; the PUSCH transmission includes a process by which the second communication node transmits data to the first communication node over a PUSCH. .

Optionally, the first set of resources is one of the following information: one or more, complete or partial, Resource sets or uplink control channel resources or uplink reserved resources; one or more, complete or partial, control resource sets, CORESET or uplink control channel resources or uplink reserved resources; one or more specific signals or specific channel resources, wherein the specific signals or specific channel resources comprise one or more of: reference signal time domain resources, reference signal frequency domain resources, synchronization signal time domain resources, synchronization signal frequency domain resources, broadcast channel time domain resources, broadcast channel frequency domain resources.

Optionally, the second set of resources comprises one of the following information: one or more, complete or partial, CORESET or uplink control channel resources or uplink reserved resources; one or more specific signals or specific channel resources, wherein the specific signals or specific channel resources comprise one or more of: reference signal time domain resources, reference signal frequency domain resources, synchronization signal time domain resources, synchronization signal frequency domain resources, broadcast channel time domain resources, broadcast channel frequency domain resources.

Optionally, the first communication node configures one or more of said first sets of resources for a second communication node; the configured time frequency resource parts of a plurality of first resource sets are prohibited from partially overlapping or prohibited from completely overlapping each other.

Optionally, when the first communication node configures a plurality of the first resource sets for the second communication node, it configures priorities for part or all of the plurality of first resource sets.

Optionally, when the time-frequency resources of a plurality of the first resource sets overlap, determining whether the overlapping time-frequency resources are allowed to be multiplexed for PDSCH or PUSCH transmission, or whether the PDSCH or PUSCH transmission needs to perform rate matching on the overlapping time-frequency resources by: and determining according to the dynamic signaling indication of the first resource set with higher priority.

Optionally, the first set of resources for the second communications node comprises one of: part of time domain resources of the time domain resource unit are the first resource set; a portion of the frequency domain resources within a frequency domain resource unit are the first set of resources.

Optionally, the first set of resources for the second communications node comprises at least one of: in the time domain, periodically configuring a part of time domain resources of a time domain resource unit as the first resource set; the time domain resource unit offset; in the frequency domain, assigning a part of frequency domain resources in a frequency domain resource unit in the range of subcarriers as the first resource set; in the frequency domain, a portion of the frequency domain resources within frequency domain resource units within a bandwidth range are designated as the first set of resources.

Optionally, when the time-frequency resources of a plurality of the first resource sets overlap, determining whether the overlapping time-frequency resources are allowed to be multiplexed for PDSCH or PUSCH transmission, or whether the PDSCH or PUSCH transmission needs to perform rate matching on the overlapping time-frequency resources by: performing an AND operation or an OR operation on the dynamic signaling indications of all of the overlapping plurality of first resource sets; depending on the result of the AND operation or OR operation.

Optionally, the following information is agreed: the dynamic signaling indication is appointed to be set to be 1, which indicates that the corresponding first resource set allows all or part of the resources to be multiplexed for PDSCH or PUSCH transmission, or the PDSCH or PUSCH transmission does not need to perform rate matching on all or part of the resources of the corresponding first resource set; setting '0' to indicate that the corresponding first resource set is prohibited to be partially or completely multiplexed to PDSCH or PUSCH transmission, or the PDSCH or PUSCH transmission needs to perform rate matching on all or part of resources of the corresponding first resource set; the dynamic signaling indication of all the overlapped multiple first resource sets is subjected to AND operation or OR operation, and the AND operation or OR operation is determined according to the result of the AND operation or OR operation, and comprises the following steps: performing an OR operation on the dynamic signaling indication of the plurality of overlapping first resource sets; and determining whether the overlapped part of the time frequency resources are allowed to be multiplexed for the PDSCH or PUSCH transmission or determining whether the PDSCH or PUSCH transmission needs to carry out rate matching on the overlapped part of the time frequency resources according to the result of the OR operation.

Optionally, in a case that it is agreed that the dynamic signaling indication setting "1" indicates that the corresponding first resource set is prohibited to be partially or fully multiplexed for PDSCH or PUSCH transmission, or the PDSCH or PUSCH transmission needs to perform rate matching on all or part of time-frequency resources of the corresponding first resource set, and setting "0" indicates that the corresponding first resource set is allowed to be fully or partially multiplexed for PDSCH or PUSCH transmission, or the PDSCH or PUSCH transmission does not need to perform rate matching on all or part of time-frequency resources of the first resource set, the method further includes: performing an AND operation on the dynamic signaling indication of the plurality of overlapping first resource sets; and determining whether the overlapped part of the time frequency resources is allowed to be multiplexed to the PDSCH or PUSCH transmission or whether the PDSCH or PUSCH transmission needs to perform rate matching on the overlapped part of the time frequency resources according to the result of the AND operation.

Optionally, when time-frequency resources of a plurality of the first resource sets overlap, the following information is determined in different manners for the first resource sets of different types: information on whether overlapping portions of time-frequency resources are allowed to be multiplexed for the PDSCH or PUSCH transmission, or whether the PDSCH or PUSCH transmission requires rate matching of overlapping portions of time-frequency resources; wherein the first set of resources of different types comprises one of: different time frequency resource allocation modes; the time frequency resource allocation ranges are different; the time frequency resource allocation granularity is different; the time frequency resources have different priorities.

Optionally, when the first resource set includes a plurality of the second resource sets or is equivalent to a plurality of the second resource sets, a plurality of the second resource sets included in the same first resource set need to satisfy at least one of the following characteristics: the second communication nodes in the plurality of second resource sets have the same blind detection time configuration or periodic configuration; the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are the same and all are slot levels, wherein the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are all slot levels used for indicating one of the following: configuring the configuration or the period of the blind detection time into each slot, and configuring the configuration or the period of the blind detection time into every other slots; the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are the same and all are mini-slot levels, wherein the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are all mini-slot levels used for indicating one of the following: the configuration or the period of the blind detection time is configured to be each mini-slot, and the configuration or the period of the blind detection time is configured to be every other plurality of mini-slots; the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are the same and are all OFDM symbol levels, wherein the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are all OFDM symbol levels for indicating one of the following: the configuration or period of the blind detection time is configured to be every OFDM symbol, and the configuration or period of the blind detection time is configured to be every other OFDM symbol; the blind detection time configuration or the periodic configuration of the plurality of second resource sets needs to satisfy an inclusion relationship, wherein the inclusion relationship is as follows: the blind detection time or period configuration of the first resource set is a subset of the blind detection time or period configuration of the second resource set; the blind detection time configurations or the periodic configurations of the plurality of second resource sets occur within a fixed time unit the same number of times, wherein the fixed time unit comprises one of: the method comprises the steps of a wireless frame, a subframe, a slot, a PDCCH region or an uplink control channel range of the slot, and a plurality of OFDM symbols with fixed numbers and fixed positions of the slot.

Optionally, the dynamic signaling indication is a multiplexing or rate matching dynamic signaling indication for a first set of resources, wherein a valid time domain range of the multiplexing or rate matching dynamic signaling indication for the first set of resources is determined to be at least one of: time-frequency resources corresponding to a first blind detection time or a first periodic configuration time at which the first resource set overlaps with resources used for the PDSCH or PUSCH transmission; time-frequency resources corresponding to all blind detection moments or all periodic configuration moments when the first resource set overlaps with resources used for the PDSCH or PUSCH transmission; the first resource set and resources used by the PDSCH or PUSCH transmission are time-frequency resources corresponding to all blind detection moments or all periodic configuration moments which are overlapped in a PDCCH region or an uplink control channel range; determining an effective time domain range according to a blind detection result of the second communication node on a time-frequency resource where the first resource set is overlapped with a resource used for the PDSCH or PUSCH transmission; a first subframe or a first slot in which the first set of resources overlaps with resources of a PDSCH or PUSCH transmission; the first set of resources is all subframes or all slots that overlap with resources of a PDSCH or PUSCH transmission.

Optionally, the PDCCH region is allowed to be in one of the following levels: subframe level, slot level, mini-slot level, OFDM symbol level; when the subframe level is adopted, the PDCCH region or the uplink control channel range is the first OFDM symbols of the subframe; when the slot level is reached, the range of the PDCCH region or the uplink control channel is the first OFDM symbols of the slot; when the uplink control channel is in a mini-slot level, the range of the PDCCH region or the uplink control channel is a plurality of first OFDM symbols of the mini-slot or a plurality of OFDM symbols of a fixed position of the slot; when the OFDM symbol level is adopted, the PDCCH region or the uplink control channel range is an OFDM symbol with a preset fixed position.

Optionally, when the second communication node detects the PDCCH sent to itself as the blind detection result, the method further includes: the second communication node performs rate matching on the detected time-frequency resources occupied by the PDCCH sent to the second communication node, and the multiplexing or rate matching dynamic signaling indication is effective for the following time for the rest of resources except the time-frequency resources occupied by the PDCCH sent to the second communication node: at the blind detection time, the first set of resources is on resources that overlap with resources used for the PDSCH transmission; or, the multiplexing or rate matching dynamic signaling indicates that the first resource set is invalid at the blind detection time; and at the blind detection time, forbidding all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission in the first resource set to be multiplexed for the PDSCH transmission, or at the blind detection time, performing rate matching on all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission in the first resource set.

Optionally, when the blind detection result of the second communication node is that the PDCCH sent to the second communication node is not detected, the method further includes: the multiplexing or rate matching dynamic signaling indication is valid for the first set of resources at the time of blind detection; or the multiplexing or rate matching dynamic signaling indicates that the first resource set is invalid at the blind detection time; and all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission in the first resource set at the blind detection time are allowed to be multiplexed for PDSCH transmission, or the PDSCH transmission does not need to perform rate matching on all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission at the blind detection time.

Optionally, the first communication node sends a dynamic indication for activating or deactivating the dynamic signaling indication to the second communication node.

Optionally, the first communication node determines the following information about the first set of resources for the second communication node: a dynamic signaling indication for indicating whether the first set of resources is multiplexed for PDSCH or PUSCH transmission or whether PDSCH or PUSCH transmission is required to perform rate matching; after performing the above steps, the first communication node sends one or more of the dynamic signaling indications to the second communication node for one or a group of the first set of resources.

Optionally, the first resource set corresponding to the dynamic signaling indication is determined by one of the following methods: semi-static configuration mode, dynamic determination mode; wherein the dynamic signaling indicates that different first resource sets are allowed to correspond to different time units, or different numbers of first resource sets are allowed to correspond to different time units; wherein the time cell comprises one of: slot, mini-slot, OFDM symbol, subframe.

Optionally, part or all of the bits of the dynamic signaling indication allow to indicate at least one of the following meanings: the part or all of the bits are used for indicating at least one of the following information of the first resource set corresponding to the adjacent bits or bit groups: multiplexing/rate matching after time domain splitting, multiplexing/rate matching after frequency domain splitting, and multiplexing/rate matching after space domain splitting; the part or all of the bits are used to indicate at least one of the following information for a particular first set of resources: multiplexing/rate matching after time domain splitting, multiplexing/rate matching after frequency domain splitting, and multiplexing/rate matching after space domain splitting; wherein the particular first set of resources is allowed to be one of: the first resource set which needs blind detection by the second communication node is used for scheduling a first resource set where a PDCCH (physical Downlink control channel) for PDSCH (physical Downlink shared channel) or PUSCH (physical Downlink shared channel) transmission is located, the first resource set which is sent by the dynamic signaling indication, and the specific first resource set which is semi-statically configured by the first communication node; the part or all of the bits are used for indicating one of the following information of all the first resource sets corresponding to all the remaining bits or bit groups: multiplexing/rate matching after time domain splitting, multiplexing/rate matching after frequency domain splitting, and multiplexing/rate matching after space domain splitting; the part or all of the bits are used for indicating whether at least one of the following conditions occurs in the following time unit: activation of a carrier and/or bandwidth part, deactivation of a carrier and/or bandwidth part, and switching of a carrier and/or bandwidth part; the part or all of the bits are used for indicating whether the length of the dynamic signaling indication sent by the subsequent time unit is changed.

Optionally, the splitting comprises: dividing at least one of the time domain, the frequency domain and the space domain of the first resource set equally; wherein, n is determined according to the number of redundant bits and is divided into n equal parts, and n is a positive integer; after the above-mentioned halving process is executed, the non-redundant bit and the redundant bit jointly indicate which halved parts of the first resource set can be multiplexed by the PDSCH or PUSCH transmission, or the PDSCH or PUSCH does not need to execute rate matching on which halved parts; wherein the redundant bits are the partial or all bits.

According to another embodiment of the present invention, there is also provided another method for determining time-frequency resources, including: the second communication node receives information about the first set of resources transmitted by the first communication node, wherein the information comprises at least one of: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed for PDSCH or PUSCH transmission, or dynamic signaling indication for performing rate matching is required for PDSCH or PUSCH transmission; determining one of the following configuration information according to the information: the method comprises the steps of allowing time frequency resources which are multiplexed to PDSCH or PUSCH transmission, and not needing to perform rate matching when the PDSCH or PUSCH is transmitted, wherein the PDSCH transmission comprises a process of transmitting data through the PDSCH, and the PUSCH transmission comprises a process of transmitting data through the PUSCH.

Optionally, the first set of resources is one of the following information: one or more, complete or partial, Resource sets or uplink control channel resources or uplink reserved resources; one or more, complete or partial, control resource sets, CORESET or uplink control channel resources or uplink reserved resources; one or more specific signals or specific channel resources, wherein the specific signals or specific channel resources comprise one of: reference signal resources, synchronization signal resources, broadcast channel resources.

Optionally, the second set of resources comprises one of the following information: one or more, complete or partial, CORESET or uplink control channel resources or uplink reserved resources; one or more specific signals or specific channel resources, wherein the specific signals or specific channel resources comprise one of: reference signal resources, synchronization signal resources, broadcast channel resources.

Optionally, the dynamic signaling indication is a multiplexing or rate matching dynamic signaling indication for a first set of resources, wherein a valid time domain range of the multiplexing or rate matching dynamic signaling indication for the first set of resources is determined to be at least one of: time-frequency resources corresponding to a first blind detection time or a first periodic configuration time at which the first resource set overlaps with resources used for the PDSCH or PUSCH transmission; time-frequency resources corresponding to all blind detection moments or all periodic configuration moments when the first resource set overlaps with resources used for the PDSCH or PUSCH transmission; the first resource set and resources used by the PDSCH or PUSCH transmission are time-frequency resources corresponding to all blind detection moments or all periodic configuration moments when a PDCCH region or an uplink control channel resource range is overlapped;

determining an effective time domain range according to a blind detection result of the second communication node on a time-frequency resource where the first resource set is overlapped with a resource used for the PDSCH or PUSCH transmission; a first subframe or a first slot in which the first set of resources overlaps with resources of a PDSCH or PUSCH transmission; the first set of resources is all subframes or all slots that overlap with resources of a PDSCH or PUSCH transmission.

Optionally, the second communication node performs blind detection, where when the blind detection result of the second communication node is that a PDCCH sent to the second communication node is detected, the method further includes: the second communication node performs rate matching on the detected time-frequency resources occupied by the PDCCH sent to the second communication node, and determines that the multiplexing or rate matching dynamic signaling indication is valid for the following time for the rest of resources except the time-frequency resources occupied by the PDCCH sent to the second communication node: the blind detection time and the first resource set are overlapped with the resources used by the PDSCH transmission; or, the second communication node determines that the multiplexing or rate matching dynamic signaling indication is invalid for the first set of resources at the blind detection time; and at the blind detection time, forbidding all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission from being multiplexed for the PDSCH transmission, or performing rate matching on all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission at the blind detection time by the PDSCH transmission.

Optionally, the second communication node performs blind detection, where when the blind detection result of the second communication node is that the PDCCH sent to the second communication node is not detected, the method further includes: the multiplexing or rate matching dynamic signaling indication is valid for the first set of resources at the time of blind detection; or the multiplexing or rate matching dynamic signaling indicates that the first resource set is invalid at the blind detection time; and all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission in the first resource set at the blind detection time are allowed to be multiplexed for PDSCH transmission, or the PDSCH transmission does not need to perform rate matching on all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission at the blind detection time.

According to another embodiment of the present invention, there is also provided an apparatus for determining time-frequency resources, including: a first determining module for determining at least one of the following information regarding the first set of resources for the second communication node: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed for PDSCH or PUSCH transmission, or dynamic signaling indication for performing rate matching is required for PDSCH or PUSCH transmission; a transmission module configured to transmit the information to the second communication node, wherein the PDSCH transmission comprises a process of transmitting data via PDSCH; the PUSCH transmission includes a process of transmitting data over a PUSCH.

According to another embodiment of the present invention, there is also provided an apparatus for determining time-frequency resources, including: a receiving module, configured to receive information regarding a first set of resources transmitted by a first communication node, wherein the information includes at least one of: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed for PDSCH or PUSCH transmission, or dynamic signaling indication for performing rate matching is required for PDSCH or PUSCH transmission; a second determining module, configured to determine one of the following configuration information according to the information: allowing time frequency resources multiplexed for PDSCH transmission, wherein the PDSCH transmission comprises a process of transmitting data through the PDSCH, and the time frequency resources do not need to perform rate matching during the PDSCH transmission; the PUSCH transmission includes a process of transmitting data to a first communication node over a PUSCH.

According to another embodiment of the present invention, there is also provided a base station including: a first processor for determining at least one of the following information regarding the first set of resources for the second communication node: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed for PDSCH or PUSCH transmission, or dynamic signaling indication for performing rate matching is required for PDSCH or PUSCH transmission; first communication means for transmitting the information to the second communication node, wherein the PDSCH transmission comprises a process of transmitting data to the second communication node over a PDSCH; the PUSCH transmission includes a process by which the second communication node transmits data to the first communication node over a PUSCH.

According to another embodiment of the present invention, there is also provided a terminal including: second communication means for receiving information regarding the first set of resources transmitted by the first communication node, wherein the information comprises at least one of: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed for PDSCH or PUSCH transmission, or dynamic signaling indication for performing rate matching is required for PDSCH or PUSCH transmission; a second processor for determining one of the following configuration information based on the information: allowing time frequency resources multiplexed for PDSCH transmission, wherein the PDSCH transmission comprises a process of transmitting data through the PDSCH, and the time frequency resources do not need to perform rate matching during the PDSCH transmission; the PUSCH transmission comprises the process of transmitting data through a PUSCH.

According to another embodiment of the present invention, there is also provided a storage medium including a stored program, wherein the program executes the method of any one of the above embodiments.

According to another embodiment of the present invention, there is also provided a processor for executing a program, wherein the program executes to perform the method of any one of the above embodiments.

By the present invention, a first communication node determines at least one of the following information about a first set of resources for a second communication node: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed for PDSCH or PUSCH transmission or not, or dynamic signaling indication for performing rate matching is required for PDSCH or PUSCH transmission; and after the information is determined, transmitting the information to a second communication node, and determining the time-frequency resources used in the PDSCH or PUSCH transmission by the second communication node according to the information. By adopting the technical scheme, the problem of how to indicate the time-frequency resources used by the PDSCH or PUSCH transmission in the related technology is solved, and the time-frequency resources used when the PDSCH or PUSCH transmission is indicated to a user are realized.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention. In the drawings:

fig. 1 is a flow chart of a method of determining timing frequency resources according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of partial overlap or full overlap according to a preferred embodiment;

FIG. 3 is a schematic diagram of a dynamic indicating manner according to a preferred embodiment of the present invention;

FIG. 4 is a schematic view according to specific embodiment 4;

FIG. 5 is a schematic view according to specific example 6;

FIG. 6 is a schematic view according to specific embodiment 9;

FIG. 7 is a schematic view according to specific embodiment 12;

FIG. 8 is a first diagram in accordance with example embodiment 13;

FIG. 9 is a first schematic diagram according to example embodiment 14;

FIG. 10 is a second schematic diagram according to specific embodiment 14;

fig. 11 is a diagram illustrating another method for configuring a first set of resources according to specific embodiment 17.

Detailed Description

The embodiment of the application provides a mobile communication network (including but not limited to a 5G mobile communication network), and the network architecture of the network can comprise a network side device (such as a base station) and a terminal. In this embodiment, an information transmission method capable of operating on the network architecture is provided, and it should be noted that an operating environment of the information transmission method provided in this embodiment is not limited to the network architecture.

The first communication node in this document may be a base station side device, and the second communication node may be a terminal side device.

Example one

In this embodiment, a method for determining time-frequency resources, which is operated in the mobile terminal network architecture, is provided, and fig. 1 is a flowchart of the method for determining time-frequency resources according to the embodiment of the present invention, as shown in fig. 1, the process includes the following steps:

step S102, the first communication node determines at least one of the following information about the first set of resources for the second communication node: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed to Physical Downlink Shared Channel (PDSCH) or Physical Uplink Shared Channel (PUSCH) transmission or not, or dynamic signaling indication for indicating whether the PDSCH or PUSCH transmission is required to execute rate matching;

step S104, transmitting the information to the second communication node, wherein the PDSCH transmission includes a process in which the first communication node transmits data to the second communication node through the PDSCH; the PUSCH transmission includes a process by which the second communication node transmits data to the first communication node over a PUSCH.

By the above steps, the first communication node determines information about the first set of resources for the second communication node; and after the information is determined, transmitting the information to a second communication node, and determining the time-frequency resources used in the PDSCH transmission by the second communication node according to the information. By adopting the technical scheme, the problem of how to indicate the time-frequency resources used by the PDSCH transmission in the related technology is solved, and the time-frequency resources used when the PDSCH transmission is indicated to a user are realized.

Alternatively, the main body of the above steps may be a base station, etc., but is not limited thereto.

Optionally, the first set of resources is one of the following information: one or more, complete or partial, Resource sets or uplink control channel resources or uplink reserved resources; one or more, complete or partial, control resource sets, CORESET or uplink control channel resources or uplink reserved resources; one or more specific signals or specific channel resources, wherein the specific signals or specific channel resources include one or more of: reference signal time domain resources, reference signal frequency domain resources, synchronization signal time domain resources, synchronization signal frequency domain resources, broadcast channel time domain resources, broadcast channel frequency domain resources.

Optionally, the second set of resources comprises one of the following information: one or more, complete or partial, CORESET or uplink control channel resources or uplink reserved resources; one or more specific signals or specific channel resources, wherein the specific signals or specific channel resources include one or more of: reference signal time domain resources, reference signal frequency domain resources, synchronization signal time domain resources, synchronization signal frequency domain resources, broadcast channel time domain resources, broadcast channel frequency domain resources.

Optionally, the first communication node configures one or more of the first set of resources for a second communication node; the time frequency resource parts of the configured first resource sets are forbidden to partially overlap or forbidden to completely overlap each other.

Optionally, the first set of resources for the second communication node comprises one of: part of time domain resources of the time domain resource unit are the first resource set; a portion of the frequency domain resources within the frequency domain resource units are the first set of resources. It should be added that, in this optional embodiment, the time domain resource unit may be a slot, a subframe, etc., where the partial time domain resource may be which OFDM symbols in a certain slot. The frequency-domain resource units may be bandwidths of a certain size, for example, the frequency-domain resource units may be N megahertz or M PRBs or Y RBGs, where N, M, or Y are positive integers.

The time domain resource unit and the frequency domain resource unit can be configured by one of the following methods: the system is pre-configured, the first communication node (which can be a base station) is configured semi-statically, and the first communication node (which can be a base station) is configured dynamically.

Optionally, the first set of resources for the second communication node comprises at least one of: in the time domain, periodically configuring a part of time domain resources of the time domain resource units as the first resource set; the time domain resource unit offset; in the frequency domain, a part of frequency domain resources in a frequency domain resource unit in the range of the subcarrier are designated as the first resource set; in the frequency domain, a portion of the frequency domain resources within frequency domain resource units within the bandwidth range are designated as the first set of resources. It should be added that this alternative embodiment shows that the first resource set may be configured periodically, that is, assuming that the fixed time domain resource is one or a group of slots, that is, selecting which OFDM symbols in each or a group of slots are used as the first resource set. Similarly, which frequency domain resource units in a certain subcarrier range are periodically configured as the first resource set in the frequency domain. See specific example 17.

Optionally, the following information is agreed: the dynamic signaling indication is appointed to be set to be 1, which indicates that the corresponding first resource set allows all or part of the resources to be multiplexed for PDSCH or PUSCH transmission, or the PDSCH or PUSCH transmission does not need to perform rate matching on all or part of the resources of the corresponding first resource set; setting '0' to indicate that the corresponding first resource set is prohibited to be partially or completely multiplexed to PDSCH or PUSCH transmission, or the PDSCH or PUSCH transmission needs to perform rate matching on all or part of resources of the corresponding first resource set; the dynamic signaling indication of all the overlapped multiple first resource sets is subjected to AND operation or OR operation, and the AND operation or OR operation is determined according to the result of the AND operation or OR operation, and comprises the following steps: performing an OR operation on the dynamic signaling indication of the plurality of overlapping first resource sets; and determining whether the overlapped part of the time frequency resources is allowed to be multiplexed to the PDSCH or PUSCH transmission or not according to the result of the OR operation, or determining whether the PDSCH or PUSCH transmission needs to perform rate matching on the overlapped part of the time frequency resources.

Optionally, in a case that it is agreed that the dynamic signaling indication setting "1" indicates that the corresponding first resource set is prohibited to be partially or completely multiplexed for PDSCH or PUSCH transmission, or the PDSCH or PUSCH transmission needs to perform rate matching on all or part of time-frequency resources of the corresponding first resource set, and setting "0" indicates that the corresponding first resource set is allowed to be fully or partially multiplexed for PDSCH or PUSCH transmission, or the PDSCH or PUSCH transmission does not need to perform rate matching on all or part of time-frequency resources of the first resource set, the method further includes: performing an AND operation on the dynamic signaling indication of the plurality of overlapping first resource sets; and determining whether the overlapped part of the time frequency resources is allowed to be multiplexed to the PDSCH or PUSCH transmission or whether the PDSCH or PUSCH transmission needs to perform rate matching on the overlapped part of the time frequency resources according to the result of the AND operation.

Optionally, when time-frequency resources of a plurality of the first resource sets overlap, the following information is determined in different manners for different types of the first resource sets: information on whether the overlapping portion of time frequency resources are allowed to be multiplexed for the PDSCH or PUSCH transmission, or whether the PDSCH or PUSCH transmission requires rate matching on the overlapping portion of time frequency resources; wherein the first set of resources of different types comprises one of: different time frequency resource allocation modes; the time frequency resource allocation ranges are different; the time frequency resource allocation granularity is different; the time frequency resources have different priorities.

Optionally, when the first resource set includes a plurality of the second resource sets or is equivalent to a plurality of the second resource sets (it should be noted herein that equivalent second resource sets may include a case where a first resource set does not include a plurality of second resource sets but configures a specific time-frequency resource of the first resource set, but the time-frequency resources are a plurality of time-frequency resources corresponding to the plurality of second resource sets and are denoted as being equivalent to the plurality of second resource sets), a plurality of the second resource sets included in the same first resource set need to satisfy at least one of the following characteristics: the second communication nodes in the plurality of second resource sets have the same blind detection time configuration or periodic configuration; the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are the same and are all slot levels, wherein the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are all slot levels used for indicating one of the following: configuring the configuration or the period of the blind detection time into each slot, and configuring the configuration or the period of the blind detection time into every other slots; the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are the same and all are mini-slot levels, wherein the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are all mini-slot levels used for indicating one of the following: the configuration or the period of the blind detection time is configured to be each mini-slot, and the configuration or the period of the blind detection time is configured to be every other plurality of mini-slots; the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are the same and are all OFDM symbol levels, wherein the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are all OFDM symbol levels for indicating one of the following: the configuration or period of the blind detection time is configured to be every OFDM symbol, and the configuration or period of the blind detection time is configured to be every other OFDM symbol; the blind detection time allocation or the periodic allocation of the plurality of second resource sets needs to satisfy an inclusion relationship, wherein the inclusion relationship is as follows: the blind detection time or period configuration of the first resource set is a subset of the blind detection time or period configuration of the second resource set; the blind detection time configurations or the periodic configurations of the plurality of second resource sets occur within a fixed time unit the same number of times, wherein the fixed time unit comprises one of the following: the method comprises the steps of a wireless frame, a subframe, a slot, a PDCCH region or an uplink control channel range of the slot, and a plurality of OFDM symbols with fixed numbers and fixed positions of the slot.

Optionally, the dynamic signaling indication is a multiplexing or rate matching dynamic signaling indication for a first set of resources, wherein a valid time domain range of the multiplexing or rate matching dynamic signaling indication for the first set of resources is determined to be at least one of: the first resource set and the time-frequency resource corresponding to the first blind detection time or the first periodic configuration time of the resource used by the PDSCH or PUSCH transmission are overlapped; time-frequency resources corresponding to all blind detection moments or all periodic configuration moments when the first resource set is overlapped with resources used for the PDSCH or PUSCH transmission; time-frequency resources corresponding to all blind detection moments or all periodic configuration moments when the resources used by the first resource set and the PDSCH or PUSCH transmission are overlapped in a PDCCH (physical Downlink control channel) domain; determining an effective time domain range according to a blind detection result of the second communication node on a time frequency resource where the first resource set is overlapped with a resource used for the PDSCH or PUSCH transmission; a first subframe or a first slot in which the first set of resources overlaps with resources for PDSCH or PUSCH transmission; the first set of resources overlaps all subframes or all slots of a PDSCH or PUSCH transmission.

Optionally, the PDCCH region or the uplink control channel resource range is allowed to be one of the following levels: subframe level, slot level, mini-slot level, OFDM symbol level; when the subframe level is adopted, the PDCCH region or the uplink control channel resource range is the first OFDM symbols of the subframe; when the slot level is adopted, the PDCCH region or the uplink control channel resource range is the first OFDM symbols of the slot; when the resource range is in a mini-slot level, the PDCCH region or the uplink control channel resource range is a plurality of first OFDM symbols of the mini-slot or a plurality of OFDM symbols at fixed positions of the slot; when the OFDM symbol level is adopted, the PDCCH region or the uplink control channel resource range is the OFDM symbol with a predetermined fixed position.

Optionally, when the second communication node detects the PDCCH sent to itself as the blind detection result, the method further includes: the second communication node performs rate matching on the detected time-frequency resources occupied by the PDCCH sent to the second communication node, and the multiplexing or rate matching dynamic signaling indication is effective for the following time for the other resources except the time-frequency resources occupied by the PDCCH sent to the second communication node: at the time of the blind detection, the first resource set overlaps with the resources used for the PDSCH transmission; or, the multiplexing or rate matching dynamic signaling indicates that the first resource set is invalid at the blind detection time; and at the time of the blind detection, forbidding all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission in the first resource set to be multiplexed for the PDSCH transmission, or, at the time of the blind detection, performing rate matching on all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission in the first resource set.

Optionally, when the blind detection result of the second communication node is that the PDCCH sent to the second communication node is not detected, the method further includes: the multiplexing or rate matching dynamic signaling indicates that the first set of resources is valid at the time of blind detection; or the multiplexing or rate matching dynamic signaling indicates that the first resource set is invalid at the blind detection time; wherein, all or part of the time frequency resources overlapped by the first resource set and the resources used by the PDSCH transmission at the blind detection time are allowed to be multiplexed for PDSCH transmission, or the PDSCH transmission does not need to perform rate matching on all or part of the time frequency resources overlapped by the first resource set and the resources used by the PDSCH transmission at the blind detection time.

Optionally, the first communication node determines the following information about the first set of resources for the second communication node: a dynamic signaling indication for indicating whether the first resource set is multiplexed for PDSCH or PUSCH transmission or whether PDSCH or PUSCH transmission is required to perform rate matching; after performing the above steps, the first communication node sends one or more dynamic signaling indications to the second communication node for one of the first set of resources or a group of the first set of resources.

Optionally, part or all of the bits of the dynamic signaling indication allow to indicate at least one of the following meanings: the part or all of the bits are used for indicating at least one of the following information of the first resource set corresponding to the adjacent bits or bit groups: multiplexing/rate matching after time domain splitting, multiplexing/rate matching after frequency domain splitting, and multiplexing/rate matching after space domain splitting; the part or all of the bits are used to indicate at least one of the following information for a particular first set of resources: multiplexing/rate matching after time domain splitting, multiplexing/rate matching after frequency domain splitting, and multiplexing/rate matching after space domain splitting; wherein the particular first set of resources is allowed to be one of: the first resource set which needs blind detection by the second communication node is used for scheduling the first resource set where the PDCCH transmitted by the PDSCH or the PUSCH is located, the dynamic signaling indicates the sent first resource set, and the first communication node semi-statically configures the specific first resource set; the part or all of the bits are used to indicate one of the following information of all the first resource sets corresponding to all the remaining bits or bit groups: multiplexing/rate matching after time domain splitting, multiplexing/rate matching after frequency domain splitting, and multiplexing/rate matching after space domain splitting; the part or all of the bits are used to indicate whether the following occurs in the subsequent time unit: activation of a carrier and/or bandwidth part, deactivation of a carrier and/or bandwidth part, and switching of a carrier and/or bandwidth part; the part or all of the bits are used for indicating whether the length of the dynamic signaling indication sent by the subsequent time unit changes.

Optionally, the splitting comprises: dividing at least one of the time domain, the frequency domain and the space domain of the first resource set equally; wherein, n is determined according to the number of redundant bits and is divided into n equal parts, and n is a positive integer; after the above-mentioned halving process is executed, the non-redundant bit and the redundant bit jointly indicate which halved parts of the first resource set can be multiplexed by the PDSCH or PUSCH transmission, or the PDSCH or PUSCH does not need to execute rate matching on which halved parts; wherein the redundant bits are the part or all of the bits.

According to another embodiment of the present invention, there is provided another method for determining time-frequency resources, including the steps of:

step one, a second communication node receives information about a first resource set transmitted by a first communication node, wherein the information comprises at least one of the following: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed for PDSCH or PUSCH transmission or not, or dynamic signaling indication for performing rate matching is required for PDSCH or PUSCH transmission;

step two, determining one of the following configuration information according to the information: allowing time frequency resources multiplexed to PDSCH or PUSCH transmission, wherein the PDSCH transmission comprises a process of transmitting data to the second communication node through the PDSCH, and the time frequency resources do not need to perform rate matching when the PDSCH or PUSCH is transmitted; the PUSCH transmission includes a process by which the second communication node transmits data to the first communication node over a PUSCH.

Optionally, the second set of resources comprises one of the following information: one or more, whole or partial CORESET; one or more specific signals or specific channel resources, wherein the specific signals or specific channel resources comprise one of: reference signal resources, synchronization signal resources, broadcast channel resources.

Optionally, the dynamic signaling indication is a multiplexing or rate matching dynamic signaling indication for a first set of resources, wherein a valid time domain range of the multiplexing or rate matching dynamic signaling indication for the first set of resources is determined to be at least one of: the first resource set and the time-frequency resource corresponding to the first blind detection time or the first periodic configuration time of the resource used by the PDSCH or PUSCH transmission are overlapped; time-frequency resources corresponding to all blind detection moments or all periodic configuration moments when the first resource set is overlapped with resources used for the PDSCH or PUSCH transmission; the first resource set and resources used by the PDSCH or PUSCH transmission are time-frequency resources corresponding to all blind detection moments or all periodic configuration moments which are overlapped in a PDCCH region or an uplink control channel resource range;

determining an effective time domain range according to a blind detection result of the second communication node on a time frequency resource where the first resource set is overlapped with a resource used for the PDSCH or PUSCH transmission; a first subframe or a first slot in which the first set of resources overlaps with resources for PDSCH or PUSCH transmission; the first set of resources overlaps all subframes or all slots of a PDSCH or PUSCH transmission.

Optionally, the second communication node performs blind detection, where when the blind detection result of the second communication node is that the PDCCH sent to the second communication node is detected, the method further includes: the second communication node performs rate matching on the detected time-frequency resources occupied by the PDCCH sent to the second communication node, and determines that the multiplexing or rate matching dynamic signaling indication is effective for the following time for the rest of resources except the time-frequency resources occupied by the PDCCH sent to the second communication node: the blind detection time and the resources used by the first resource set and the PDSCH transmission are overlapped; or, the second communication node determines that the multiplexing or rate matching dynamic signaling indication is invalid for the first resource set at the blind detection time; and at the blind detection time, forbidding all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission in the first resource set to be multiplexed for PDSCH transmission, or performing rate matching on all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission at the blind detection time in the PDSCH transmission.

Optionally, the second communication node performs blind detection, where when the blind detection result of the second communication node is that the PDCCH sent to the second communication node is not detected, the method further includes: the multiplexing or rate matching dynamic signaling indicates that the first set of resources is valid at the time of blind detection; or the multiplexing or rate matching dynamic signaling indicates that the first resource set is invalid at the blind detection time; wherein, all or part of the time frequency resources overlapped by the first resource set and the resources used by the PDSCH transmission at the blind detection time are allowed to be multiplexed for PDSCH transmission, or the PDSCH transmission does not need to perform rate matching on all or part of the time frequency resources overlapped by the first resource set and the resources used by the PDSCH transmission at the blind detection time.

The following are specific examples of preferred embodiments of the invention.

Specific example 1:

the base station semi-statically configures a plurality of Resource sets for the terminal, and can configure the Resource sets through RRC signaling, and the configured Resource sets do not overlap with each other in time-frequency resources.

When the base station configures a Resource set for the terminal, in addition to configuring a time-frequency Resource occupied by the Resource set in one time-frequency Resource unit, the base station needs to configure which time-frequency Resource units the Resource set appears in, or the terminal needs to configure the Resource set and a time domain configuration in the time-frequency Resource units in which time-frequency Resource units the Resource set is described by a monitor, and the time domain configuration in the time-frequency Resource units can be configured by adopting a period and/or a time unit offset and/or a time unit pattern. The frequency domain configuration in the time frequency resource unit may be configured with a carrier and/or a bandwidth part within the carrier and/or a number of RBGs on the bandwidth part within the carrier and/or a number of PRBs on the bandwidth part within the carrier.

If the base station does not configure which time frequency Resource units the Resource set appears in, the terminal may regard that the Resource set appears in each time frequency Resource unit, or the terminal needs to monitor the Resource set in all time frequency Resource units.

Specific example 2:

the base station semi-statically configures a plurality of Resource sets for the terminal, and may be configured through RRC signaling, where the configured plurality of Resource sets may overlap each other by time-frequency resources, where the overlap may be partial overlap and/or full overlap, fig. 2 is a schematic diagram of partial overlap or full overlap according to the preferred embodiment, and as shown in fig. 2, from left to right, full overlap, partial overlap, and full overlap are respectively shown.

When configuring Resource sets, the base station indicates the priority of each Resource set or Resource sets with Resource overlapping in an explicit or implicit mode.

The specific explicit mode is a semi-static configuration or a priority sequence number x of a system pre-configured Resource set, wherein x is an integer, and the priority sequence number from small to large indicates that the priority is from high to low, or the priority sequence number from large to small indicates that the priority is from high to low.

Or the specific display mode is semi-static configuration or the system is preconfigured to meet the Resource set of the characteristic 1 as high priority, and the rest of the Resource sets which do not meet the characteristic 1 are low priority.

The specific feature 1 may be one of the following, but is not limited to the following: resource set containing all or part of the time frequency resources satisfying the characteristic 2; the configuration satisfies Resource set of feature 3.

The feature 2 may be one of, but is not limited to, the following: the reference signal is a specific or dedicated time-frequency resource, such as a time-frequency resource occupied by a certain reference signal, specifically, the reference signal may be a synchronization signal, a CSI-RS, an SRS, a DMRS, a PTRS, or the like; the time-frequency resource occupied by a certain common channel may specifically be a PBCH, a channel carrying system messages, and the like; is to reserve resources.

The feature 3 may be one of, but is not limited to, the following: including certain configuration granularity, such as RE-level configuration granularity or RB-level configuration granularity; configuring signaling into a specific format; the configuration signaling is of a certain length or greater.

Specifically, the implicit mode is that the priority order is represented by the Resource set Index itself, and the priority of the Resource set Index is from high to low from low to high, or the priority of the Resource set Index is from high to low.

When the dynamic signaling indicates whether the Resource set or partial resources of the Resource set need to be rate matched by the PDSCH resources, for a plurality of Resource sets with overlapped resources, if the dynamic signaling indication of the Resource sets is consistent, namely the Resource sets need to be rate matched or do not need to be rate matched, the rate matching of the PDSCH is carried out according to the dynamic signaling indication; if the dynamic signaling indications of the resources are inconsistent, some Resource sets or partial resources thereof need to be rate-matched, and some Resource sets or partial resources thereof do not need to be rate-matched, whether rate matching is needed or not can be determined according to the indication of the Resource sets or partial resources thereof with high priority.

Specific example 3:

the base station semi-statically configures a plurality of Resource sets for the terminal, and can use RRC signaling for configuration.

The base station sends dynamic signaling to the terminal to indicate which Resource set resources can be occupied by overlapped PDSCH corresponding to the scheduled PDSCH transmission, namely, the base station does not need to perform rate matching, and which Resource set resources can not be occupied by overlapped PDSCH, namely, the base station needs to perform rate matching.

For a plurality of Resource sets with Resource overlapping, if the dynamic signaling indication is different, for the overlapping area, as long as the dynamic signaling indication corresponding to at least one of the Resource sets is not used for rate matching, the overlapping area does not use for rate matching for the PDSCH. The overlap region needs to rate match the PDSCH only if the dynamic signaling indications for all Resource sets that overlap indicate that rate matching is needed.

If the dynamic signaling indication corresponding to a certain Resource set is set to '1' to indicate that rate matching is not needed, and set to '0' to indicate that rate matching is needed, for the overlapping area of multiple Resource sets, an 'or' operation needs to be performed according to the dynamic signaling indication of each Resource set to which the overlapping area belongs, the Resource multiplexing/rate matching condition for the overlapping area is determined according to the result of the 'or' operation, if the result of the 'or' operation is '1', rate matching is not needed to be performed on the overlapping area, and if the result of the 'or' operation is '0', rate matching is needed to be performed on the overlapping area.

If the dynamic signaling indication corresponding to a certain Resource set is set to '1' to indicate that rate matching is needed, and set to '0' to indicate that rate matching is not needed, for the overlapping area of a plurality of Resource sets, an 'AND' operation needs to be performed according to the dynamic signaling indication of each Resource set to which the overlapping area belongs, and the Resource multiplexing/rate matching condition for the overlapping area is determined according to the result of the 'AND' operation, if the result of the 'AND' operation is '0', the rate matching is not needed to be performed on the overlapping area, and if the result of the 'AND' operation is '1', the rate matching is needed to be performed on the overlapping area.

In this embodiment, fig. 3 is a schematic diagram of a dynamic indication manner according to a preferred embodiment of the present invention, as shown in fig. 3, a black small block in Resource set1 represents a PDCCH for scheduling a PDSCH, and for a PDCCH Resource for scheduling a PDSCH, regardless of whether the rest of the Resource set in which the PDCCH Resource is located needs to be rate-matched by the PDSCH, time-frequency resources occupied by the PDCCH for scheduling the PDSCH always need to be rate-matched by the PDSCH. In addition, if the terminal blindly detects a common PDCCH or a group-common PDCCH in a certain Resource set, the time-frequency resources occupied by the common PDCCH and/or the group-common PDCCH always need to be rate-matched by the PDSCH, regardless of whether the Resource set needs to be rate-matched by the PDSCH.

Specific example 4:

The base station sends dynamic signaling to the terminal to indicate which Resource set resources can be occupied by overlapped PDSCH corresponding to the scheduled PDSCH transmission, namely, the base station does not need to perform rate matching, and which Resource set resources can not be occupied by overlapped PDSCH, namely, the base station needs to perform rate matching. The dynamic signaling indication may be valid on a partial OFDM symbol of one slot.

Fig. 4 is a diagram according to specific embodiment 4, and as shown in fig. 4, a PDCCH for scheduling a PDSCH is sent in Resource set1, a dynamic signaling indication of whether a semi-statically configured Resource set Resource is multiplexed for the PDSCH is sent in the PDCCH or other PDCCHs, and assuming that the dynamic signaling indication for Resource set1 is '1', it indicates that the PDSCH may multiplex all or part of time-frequency resources of Resource set1, and the PDSCH does not need to rate-match all or part of the time-frequency resources of Resource set 1. The dynamic signaling indication for Resource set2 is '0', which indicates that the PDSCH cannot multiplex all or part of the time-frequency resources of Resource set2, and the PDSCH needs to perform rate matching on all or part of the time-frequency resources of Resource set 2.

Resource set1 and Resource set2 have their own Monitor occasion configuration, and the Monitor occasion configuration of Resource set1 is slot level, specifically, each slot needs a Monitor or each slots needs a Monitor, and there is at most one Monitor occasion in one slot. The Monitor occasion of Resource set2 is configured to mini-slot or OFDM symbol level, with multiple Monitor occasions in a slot.

The dynamic signaling indications for Resource set1 and Resource set2 are valid only at one Monitor occasion, specifically: and in the slot where the dynamic signaling indicates the corresponding PDSCH transmission, Resource set1, Resource set2 and the first Monitor scheduling of the PDSCH Resource allocation overlap, taking fig. 4 as an example, for Resource set1, the effective Monitor scheduling is occupancy 1 of Resource set 1. For Resource set2, the valid Monitor occase is Occasion1 at Resource set 2.

Specific example 5:

still taking fig. 4 as an example, the dynamic signaling indications for Resource set1 and Resource set2 are valid for all Monitor sessions where the corresponding Resource set overlaps the corresponding PDSCH Resource allocation. The method specifically comprises the following steps: and in the slot where the dynamic signaling indicates the corresponding PDSCH transmission, Resource set1, Resource set2 and all Monitor sessions in which the PDSCH Resource allocation is overlapped, taking fig. 4 as an example, for Resource set1, the effective Monitor session is occupancy 1 of Resource set 1. For Resource set2, Occasion1 and Occasion2 with valid Monitor Occasion being Resource set 2.

Specific example 6:

fig. 5 is a schematic diagram according to specific embodiment 6, as shown in fig. 5, for the dynamic signaling indications of Resource set1 and Resource set2, all Monitor sessions in the PDCCH region where the corresponding Resource set overlaps with the corresponding PDSCH Resource allocation are valid. Usually, the PDCCH region is the first several OFDM symbols of one slot, and in the PDCCH region, dynamic signaling indications are valid for all Monitor instances where Resource set1, Resource set2 and PDSCH Resource allocation overlap. Taking FIG. 5 as an example, for Resource set1, Occasion1 with a valid Monitor occase being Resource set 1. For Resource set2, occupancy 1 and occupancy 2 with valid Monitor occupancy as Resource set2, occupancy 3 overlaps the PDSCH Resource allocation, but because occupancy 3 is not in the PDCCH region, dynamic signaling indicates that occupancy 3 is not valid for Resource set 2.

Specific example 7:

still taking fig. 4 as an example, the valid ranges for the dynamic signaling indications of Resource set1 and Resource set2 are related to the blind detection situation of the terminal. The method specifically comprises the following steps: the first Monitor Occasion that the corresponding Resource set overlaps the corresponding PDSCH Resource allocation is valid, i.e. Occasion1 for Resource set1 and Occasion1 for Resource set2 in FIG. 4. For other overlapping Monitor occasions, i.e., Occasion2 of Resource set2 in fig. 4, whether the dynamic signaling indication is valid depends on the blind detection result of the Resource set by the terminal on the corresponding Monitor Occasion.

Blind detection included the following:

1) if the terminal does not blindly detect the PDCCH sent by the base station to itself on the corresponding occupancy,

then, the time-frequency Resource determination that the Resource set corresponding to the occupancy overlaps with the Resource allocation of the corresponding PDSCH on the occupancy can be used for PDSCH transmission, i.e. the terminal does not need to perform rate matching on the PDSCH on the corresponding time-frequency Resource, and is irrelevant to dynamic signaling indication; alternatively, the dynamic signaling indicates that the indication for this Resource set continues to be valid.

2) If the terminal detects the PDCCH sent by the base station to the terminal on the corresponding Ocvasion,

then, the corresponding Resource set on the occupancy cannot be used for PDSCH transmission, i.e. the terminal needs to perform rate matching on the PDSCH on the corresponding time-frequency Resource, and is unrelated to the dynamic signaling indication.

Or, in the Resource set corresponding to the occupancy, resources other than the time-frequency resources occupied by the PDCCH that is detected by the terminal in a blind manner, and the indication of the dynamic signaling indication for the Resource set continues to be valid.

Specific example 8:

taking fig. 5 as an example, the valid ranges of the dynamic signaling indications for Resource set1 and Resource set2 are related to the blind detection situation of the terminal. The method specifically comprises the following steps: all Monitor sessions in the PDCCH region where the corresponding Resource set overlaps the corresponding PDSCH Resource allocation are valid, i.e. occupancy 1 for Resource set1, occupancy 1 and occupancy 2 for Resource set2 in fig. 5. For other overlapping Monitor occasions, i.e., Occasion3 of Resource set2 in fig. 5, whether the dynamic signaling indication is valid depends on the blind detection result of the Resource set by the terminal on the corresponding Monitor Occasion.

The blind detection results are as follows:

1) if the terminal does not blindly detect the PDCCH sent by the base station to the terminal on the corresponding Ocvasion,

the time frequency Resource determination of the overlapping of the corresponding Resource set and the corresponding PDSCH Resource allocation on the occupancy can be used for PDSCH transmission, namely the terminal does not need to perform rate matching on the PDSCH on the corresponding time frequency Resource and is irrelevant to dynamic signaling indication. Alternatively, the dynamic signaling indicates that the indication for this Resource set continues to be valid.

the corresponding Resource set on the occupancy cannot be used for the transmission of the PDSCH, that is, the terminal needs to perform rate matching on the PDSCH on the corresponding time-frequency Resource, and is irrelevant to the dynamic signaling indication.

Specific example 9:

fig. 6 is a schematic diagram according to specific embodiment 9, as shown in fig. 6, a PDSCH scheduled in Resource set1 may occupy multiple slots, and then a dynamic signaling indication of multiplexing resources corresponding to the PDSCH transmission sent by a base station to a terminal is only valid on a first slot allocated to the PDSCH resources and is invalid on other slots allocated to the PDSCH resources, that is, in fig. 5, for the dynamic signaling indications of Resource set1 and Resource 2, only valid on slot1 and invalid on slot 2.

Specific example 10:

as shown in fig. 6, the PDSCH scheduled in Resource set1 may occupy multiple slots, and then the multiplexing Resource dynamic signaling indication sent by the base station to the terminal and corresponding to the PDSCH transmission is valid on all slots included in the PDSCH Resource allocation, that is, in fig. 5, the dynamic signaling indications of Resource set1 and Resource set2 are valid on both slots 1 and slots 2.

Specific example 11:

as shown in fig. 6, a PDSCH scheduled in Resource set1 may occupy multiple slots, and then a multiplexing Resource dynamic signaling indication corresponding to PDSCH transmission sent by a base station to a terminal is valid on the first slot allocated by the PDSCH Resource, that is, valid on slot1 in fig. 5; for other slots contained in the PDSCH Resource allocation, that is, slot2 in fig. 5, dynamic signaling 2 needs to be further indicated, and according to the indication of dynamic signaling 2, it is determined whether the corresponding Resource set on slot2 can be multiplexed by the PDSCH scheduled by Resource set1, where the dynamic signaling 2 may specifically be one of the following:

an active/inactive indication of the dynamic signaling indication sent in slot 1;

the new dynamic signaling indication is independent of the dynamic signaling indication sent in slot1, and the indicated Resource set may also be different from the dynamic signaling indication sent in slot 1.

Specific example 12:

when the gNB configures Resource set time-frequency resources, if one Resource set includes multiple coreslets, and multiple coreslets configured in one Resource set, their Monitor sessions should meet certain requirements, and the specific requirements may be a combination of one or more of the following:

1) the Monitor occasion configuration of each CORESET is completely the same, namely blind detection is carried out on the same wireless frame or subframe or slot or OFDM symbol;

2) the configuration levels of Monitor occasting of each CORESET are the same and are slot levels, specifically, blind detection of each slot or blind detection of every multiple slots is performed;

3) the configuration levels of the Monitor occasions of the CORESETs are the same and are all mini-slot levels, and specifically, the blind detection can be performed on each mini-slot or every other multiple mini-slots;

4) the Monitor interference configuration level of each CORESET is the same, and all OFDM symbol levels are the same, specifically, each OFDM symbol can be detected blindly, or every other OFDM symbol can be detected blindly.

5) The Monitor occast configuration of each CORESET needs to satisfy the inclusion relationship, such as the CORESET with sparse blind detection times and the CORESET with dense blind detection times, the blind detection time of the former is a subset of the busy detection time of the latter, fig. 7 is a schematic diagram according to embodiment 12, as shown in fig. 7, CORESET1 and CORESET4 can be configured in the same Resource set, because the Monitor occast of CORESET1 is every slot, the Monitor occast of CORESET4 is every odd slot, and the Monitor occast of CORESET4 is a subset of the Monitor occast of CORESET 1. CORESET2 and CORESET3 can be configured in the same Resource set, because the Monitor localization of CORESET2 is OFDM symbol { 02512 } for each slot, and the Monitor localization of CORESET3 is OFDM symbol {5} for each slot, so the Monitor localization of CORESET3 is a subset of the Monitor localization of CORESET 2.

The number of times that the Monitor occasions of each CORESET are configured in a fixed time unit is the same, for example, one slot is taken as the fixed time unit, and CORESETs with the number of times that the Monitor occasions are 1 in one slot can be configured in one Resource set, as shown in FIG. 7, CORESET1 and CORESET3 can be configured in the same Resource set, and the number of times that the Monitor occasions are in one slot is 1.

After configuring a Resource set containing multiple CORESETs according to the above rules, the dynamic signaling indication for the Resource set is valid for the corresponding unit time, and the specific unit time may be one subframe or multiple subframes, or one slot or multiple slots, or one slot PDCCH region or multiple slot PDCCH regions, or a fixed number of OFDM symbols, and the dynamic signaling indication is followed on the time-frequency resources overlapped with PDSCH Resource allocation for all Monitor instances of all CORESETs contained in the Resource set in the unit time.

Or after configuring a Resource set including multiple CORESET according to the above rules, indicating that the single-time Monitor occasion is valid for the dynamic signaling of the Resource set, where the single-time Monitor occasion may be a time-frequency Resource where the Resource set and PDSCH Resource are overlapped, and the time-frequency Resource corresponding to the first Monitor occasion of each CORESET included in the Resource set.

Specific example 13:

For multiple Resource set overlap regions, which principle is applied to determine whether scheduled PDSCH transmission is rate-matched to the overlap region may be configured by the base station, may be semi-statically configured through RRC signaling or system message, or may be dynamically configured through PDCCH.

For multiple Resource set overlap regions, different principles may be applied to determine whether scheduled PDSCH transmissions are rate matched to the overlap regions. For example, different principles may be applied to Resource sets of different configuration manners or containing different types of time-frequency resources, fig. 8 is a schematic diagram according to a first specific embodiment 13, as shown in fig. 8, Resource set1 and Resource set2 are configured in a configuration manner of 1, or Resource set1 and Resource set2 are configured in a Resource set containing type 1 time-frequency resources, Resource set3 is configured in a configuration manner of 2, or Resource set3 is configured in a Resource set containing type 2 time-frequency resources, and then, for an overlapping area OA1 of Resource set1 and Resource set2, it is determined whether the PDSCH needs to rate-match OA1 according to principle 1; for the overlap area OA2 of Resource set1 and Resource set3, it is determined according to principle 2 whether PDSCH needs to be rate matched to OA 2.

Principle 1 and principle 2 may be one of the following:

1) in the overlapped Resource sets, as long as one Resource set is indicated by the dynamic signaling as not being multiplexed by the PDSCH, the PDSCH is required to perform rate matching on the Resource sets, and no matter whether other Resource sets require the PDSCH to perform rate matching on the Resource sets, the overlapped region cannot be multiplexed by the PDSCH and requires the PDSCH to perform rate matching on the overlapped region;

2) in the overlapped Resource sets, as long as one Resource set is indicated by dynamic signaling to be multiplexed by the PDSCH, the PDSCH is not required to perform rate matching on the Resource sets, and no matter whether other Resource sets need the PDSCH to perform rate matching on the Resource sets or not, the overlapped region can be multiplexed by the PDSCH and the PDSCH is not required to perform rate matching on the Resource sets;

3) and according to the Resource set priority of semi-static configuration or system pre-configuration or the Resource set priority equal to the semi-static configuration or system pre-configuration, when the Resource set with high priority is overlapped with the Resource set with low priority, the method determines whether the overlapped region can be multiplexed by the PDSCH and whether the PDSCH needs to perform rate matching on the overlapped region or not according to the dynamic signaling indication of the Resource set with high priority.

Specific example 14:

the dynamic signaling indication may contain 1 or more bits for indicating whether 1 or more Resource set time-frequency resources may be used by the scheduled PDSCH transmission, or whether the scheduled PDSCH transmission needs to rate match the Resource set resources. The specific Resource set indicated by a certain bit or a plurality of bits in the dynamic signaling indication may be configured semi-statically or may be changed dynamically.

Fig. 9 is a schematic diagram according to specific embodiment 14, as shown in fig. 9, when a semi-static configuration manner is adopted, a base station may configure, through RRC signaling or system information, an xth bit or a bit group in a dynamic signaling indication corresponding to Resource set1 and Resource set2, where Resource set3 corresponds to a yth bit or a bit group in the dynamic signaling indication, x and y are positive integers not exceeding the length of the dynamic signaling indication, time-frequency resources corresponding to Resource set1 and Resource set2 may be the same or different in one slot, and the base station may perform semi-static configuration through RRC signaling or system information. The configuration periods and/or time domain offsets and/or Monitor cases of Resource set1 and Resource set2 are different, and these parameters are also configured semi-statically by the base station through RRC signaling or system messages. Therefore, the base station can configure the time unit appearing in Resource set1 in a semi-static manner through RRC signaling or system messages, the x-th bit or bit group in the dynamic signaling indication corresponds to Resource set1, the x-th bit or bit group in the dynamic signaling indication corresponds to Resource set2 in the time unit appearing in Resource set2, and the y-th bit or bit group in the dynamic signaling indication always corresponds to Resource set 3.

As shown in fig. 9, when a dynamic mode is adopted, a base station configures Resource set1 and Resource set2 to correspond to the xth bit or bit group in a dynamic signaling indication through RRC signaling or system message, Resource set3 corresponds to the yth bit or bit group in the dynamic signaling indication, x and y are positive integers not exceeding the length of the dynamic signaling indication, time-frequency resources corresponding to Resource set1 and Resource set2 may be the same or different in one slot, and the base station is configured semi-statically through RRC signaling or system message. The configuration periods and/or time domain offsets and/or Monitor cases of Resource set1 and Resource set2 are different, and these parameters are also configured semi-statically by the base station through RRC signaling or system messages. According to the configuration of the base station, the terminal may determine that only Resource set1 or Resource set2 exists in a time unit (which may be a subframe or slot or a mini-slot or OFDM symbol group) scheduled by a certain PDSCH, so that the xth bit or bit group corresponds to the existing Resource set, which may be Resource set1 or Resource set2, and the yth bit or bit group in the dynamic signaling indication always corresponds to Resource set 3.

The configurations of Resource set1 and Resource set2 may also be as shown in fig. 10, where fig. 10 is a diagram second according to embodiment 14, then the xth bit or bit group in the dynamic signaling indication corresponds to Resource set1 in some time units (e.g., slot1, 3,5), and corresponds to Resource set1 and Resource set2 in some time units (e.g., slot2, 4,6), that is, the xth bit or bit group, the corresponding Resource set index, and the number of Resource sets may be different, specifically, also may be configured semi-statically, or determined by the terminal according to the configuration of Resource sets.

Specific example 15:

the length of the dynamic signaling configured by the base station is m bits, the candidate multiplexing Resource sets required to be indicated by the dynamic signaling configured by the base station are m +1, and then which Resource set corresponds to the m bits of the dynamic signaling from the bottom depends on the Resource sets existing in a certain time unit and the Resource sets overlapped with the scheduled PDSCH transmission Resource allocation.

Taking m as an example, the dynamic signaling length is 2 bits, and the candidate multiplexing Resource sets to be indicated are 3, which are respectively denoted as Resource set1, Resource set2, and Resource set 3.

If 3 Resource sets exist in a certain time unit and all the 3 Resource sets overlap with the PDSCH transmission Resource allocation scheduled by the current time unit, then one or a combination of the following is adopted for processing:

according to the sequence number or priority order of the Resource sets, the dynamic signaling of 2 bits in the last Resource set cannot indicate the multiplexing situation, that is, the Resource set cannot be multiplexed to the PDSCH by default by the terminal, and the PDSCH needs to perform rate matching on the Resource set.

According to the sequence number of the Resource sets or the priority sequence, the Resource sets arranged in the last two bits are jointly indicated by 1 bit in the dynamic signaling indication, namely, the two Resource sets are subjected to consistent multiplexing or non-multiplexing treatment.

If at a certain time unit there are and the number of Resource sets overlapping the PDSCH transmission Resource allocation scheduled by the current time unit is exactly 2, then 2 bits of the dynamic signaling indicate 2 Resource sets, one-to-one correspondence, respectively.

If at a certain time unit there is a Resource set number that is less than 2, e.g. 1, and that overlaps the PDSCH transmission Resource allocation scheduled at the current time unit, then there is a redundant bit in the dynamic indication signalling.

Specific example 16:

when the dynamic indication signaling transmitted in a certain time unit contains a redundant number of bits compared with the Resource set number required to be indicated in the current time unit, the redundant bits can be used for one or more of the following combinations:

the redundant bits are used to indicate the multiplexing/rate matching situation after time domain and/or frequency domain and/or spatial domain splitting of Resource sets corresponding to adjacent bits or bit groups.

The redundant bits are used to indicate the multiplexing/rate matching case after time and/or frequency and/or spatial splitting of a particular Resource set. The specific Resource set may be a Resource set that the terminal needs a monitor, or a Resource set of a PDCCH receiving a scheduled PDSCH transmission, or a Resource set sent by a dynamic signaling indication, or a specific Resource set semi-statically configured by the base station.

The redundant bits are used to indicate the multiplexing/rate matching situation after time domain and/or frequency domain and/or spatial domain splitting of all Resource sets corresponding to all the remaining bits or bit groups.

The redundancy bits are used to indicate whether activation or deactivation or switching of the carrier and/or bandwidth portions occurs for subsequent time units. The splitting is as follows: the time domain and/or the frequency domain and/or the space domain corresponding to the Resource set are equally divided, and n is determined to be specifically equally divided according to the number of redundant bits, wherein n is a positive integer. After the equal division processing, the non-redundant bits and the redundant bits jointly indicate which equal parts can be multiplexed by PDSCH transmission after the corresponding Resource set is equal divided, or the PDSCH does not need to perform rate matching on the equal parts.

The redundant bit is used for indicating whether the length of the dynamic signaling indication sent by the subsequent time unit changes. If the state '0' indicates no change, and the state '1' indicates a change, specifically a length shortening or increasing z bits, z may be equal to the number of redundant bits or equal to 1 or not limited thereto.

Specific example 17:

the base station configures one or more Resource sets for the terminal, wherein some of the Resource sets may be configured to include one or more complete or partial CORESET, and the other Resource sets are configured independently of the CORESET, or although specific time-frequency resources overlap with the CORESET, the Resource sets are not configured with specific CORESET sequence numbers, but are directly and explicitly configured with specific time-frequency resources included in the Resource sets.

For example, the time domain Resource unit may be a slot or a subframe, and the base station configures a Resource set to occupy a part of OFDM symbols in the time domain Resource unit.

The frequency domain Resource unit may be N PRBs, such as 25 PRBs or 50 PRBs, and the base station configures a Resource set to occupy a part of PRBs in one frequency domain Resource unit.

The time domain Resource unit may be 1 time domain Resource unit or multiple time domain Resource units in the time domain, and if the time domain Resource unit is configured to be 2 slots, it indicates that, in every 2 slots, a part of OFDM symbols of 1 slot is the time domain Resource of the Resource set. The time domain Resource unit offset in the time domain indicates that the time domain Resource of the Resource set exists in the second time domain Resource unit in one time domain period, and if the configuration offset is 1, the time domain Resource unit offset indicates that part of the OFDM symbols in the first time domain Resource unit in each time domain period are the time domain Resource of the Resource set.

The period of the frequency domain Resource unit in the frequency domain may be one frequency domain Resource unit or multiple frequency domain Resource units, and may be limited to one or multiple carrier bandwidths or one or multiple partial bandwidths of one carrier bandwidth, if 2 frequency domain Resource units are configured, it indicates that in every 2 frequency domain Resource units, a partial PRB of 1 frequency domain Resource unit is the frequency domain Resource of the Resource set. The offset of the frequency domain Resource unit in the frequency domain indicates that the frequency domain Resource of the Resource set exists in the several frequency domain Resource units in one frequency domain period, and if the offset is configured to be 1, the offset indicates that a part of PRBs in the first frequency domain Resource unit in each frequency domain period are the frequency domain Resource of the Resource set.

Fig. 11 is a schematic diagram of another method for configuring a first resource set according to specific embodiment 17, and an illustration of the above text description is given as shown in fig. 11.

Through the above description of the embodiments, those skilled in the art can clearly understand that the method according to the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but the former is a better implementation mode in many cases. Based on such understanding, the technical solutions of the present invention may be embodied in the form of a software product, which is stored in a storage medium (e.g., ROM/RAM, magnetic disk, optical disk) and includes instructions for enabling a terminal device (e.g., a mobile phone, a computer, a server, or a network device) to execute the method according to the embodiments of the present invention.

Example two

In this embodiment, a device for determining time-frequency resources is further provided, where the device is used to implement the foregoing embodiments and preferred embodiments, and details are not repeated for what has been described. As used below, the term "module" may be a combination of software and/or hardware that implements a predetermined function. Although the means described in the embodiments below are preferably implemented in software, an implementation in hardware, or a combination of software and hardware is also possible and contemplated.

According to another embodiment of the present invention, there is also provided an apparatus for determining time-frequency resources, which is applied to a first communication node, and includes:

a first determining module for determining at least one of the following information regarding the first set of resources for the second communication node: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed for PDSCH or PUSCH transmission, or dynamic signaling indication for performing rate matching is required for PDSCH or PUSCH transmission;

a transmission module configured to transmit the information to the second communication node, wherein the PDSCH transmission comprises a process of transmitting data to the second communication node via PDSCH; the PUSCH transmission comprises a process in which the second communication node transmits data to the first communication node through a PUSCH

It should be added that, in the first embodiment, the method embodiments executed by the first determining module can be executed by the apparatus applied to the first determining module.

Optionally, the first set of resources is one of the following information: one or more, full or partial Resource sets; one or more, whole or partial CORESET; one or more specific signals or specific channel resources, wherein the specific signals or specific channel resources comprise one or more of: reference signal time domain resources, reference signal frequency domain resources, synchronization signal time domain resources, synchronization signal frequency domain resources, broadcast channel time domain resources, broadcast channel frequency domain resources.

Optionally, the second set of resources comprises one of the following information: one or more, whole or partial CORESET; one or more specific signals or specific channel resources, wherein the specific signals or specific channel resources comprise one or more of: reference signal time domain resources, reference signal frequency domain resources, synchronization signal time domain resources, synchronization signal frequency domain resources, broadcast channel time domain resources, broadcast channel frequency domain resources.

Optionally, the first determining module configures one or more of the first resource sets for a second communication node; the configured time frequency resource parts of a plurality of first resource sets are prohibited from partially overlapping or prohibited from completely overlapping each other.

Optionally, when the first determining module configures a plurality of first resource sets for the second communication node, the first determining module configures priorities for part or all of the plurality of first resource sets.

Optionally, when the time-frequency resources of a plurality of the first resource sets overlap, determining whether the overlapping time-frequency resources are allowed to be multiplexed for PDSCH transmission, or whether PDSCH transmission needs to perform rate matching on the overlapping time-frequency resources by: and determining according to the dynamic signaling indication of the first resource set with higher priority.

Optionally, when the time-frequency resources of a plurality of the first resource sets overlap, determining whether the overlapping time-frequency resources are allowed to be multiplexed for PDSCH transmission, or whether PDSCH transmission needs to perform rate matching on the overlapping time-frequency resources by: performing an AND operation or an OR operation on the dynamic signaling indications of all of the overlapping plurality of first resource sets; depending on the result of the AND operation or OR operation.

Optionally, the following information is agreed: the dynamic signaling indication is appointed to be set to be 1, which indicates that the corresponding first resource set allows all or part of the resources to be multiplexed for PDSCH transmission, or the PDSCH transmission does not need to perform rate matching on all or part of the resources of the corresponding first resource set; setting '0' to indicate that the corresponding first resource set is prohibited to be partially or completely multiplexed for PDSCH transmission, or the PDSCH transmission needs to perform rate matching on all or part of resources of the corresponding first resource set; the dynamic signaling indication of all the overlapped multiple first resource sets is subjected to AND operation or OR operation, and the AND operation or OR operation is determined according to the result of the AND operation or OR operation, and comprises the following steps: performing an OR operation on the dynamic signaling indication of the plurality of overlapping first resource sets; and determining whether the overlapped part of the time frequency resources is allowed to be multiplexed for the PDSCH transmission or determining whether the PDSCH transmission needs to perform rate matching on the overlapped part of the time frequency resources according to the result of the OR operation.

Optionally, in a case that it is agreed that the dynamic signaling indication setting "1" indicates that the corresponding first resource set is prohibited from being partially or completely multiplexed for PDSCH transmission, or that the PDSCH transmission needs to perform rate matching on all or part of time-frequency resources of the corresponding first resource set, and setting "0" indicates that the corresponding first resource set is allowed to be fully or partially multiplexed for PDSCH transmission, or that the PDSCH transmission does not need to perform rate matching on all or part of time-frequency resources of the first resource set, the method further includes: performing an AND operation on the dynamic signaling indication of the plurality of overlapping first resource sets; and determining whether the overlapped part of the time frequency resources is allowed to be multiplexed for the PDSCH transmission or whether the PDSCH transmission needs to perform rate matching on the overlapped part of the time frequency resources according to the result of the AND operation.

Optionally, when time-frequency resources of a plurality of the first resource sets overlap, the following information is determined in different manners for the first resource sets of different types: information on whether overlapping portions of time-frequency resources are allowed to be multiplexed for the PDSCH transmission, or whether the PDSCH transmission requires rate matching to overlapping portions of time-frequency resources; wherein the first set of resources of different types comprises one of: different time frequency resource allocation modes; the time frequency resource allocation ranges are different; the time frequency resource allocation granularity is different; the time frequency resources have different priorities.

Optionally, when the first resource set includes a plurality of the second resource sets or is equivalent to a plurality of the second resource sets, a plurality of the second resource sets included in the same first resource set need to satisfy at least one of the following characteristics: the second communication nodes in the plurality of second resource sets have the same blind detection time configuration or periodic configuration; the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are the same and all are slot levels, wherein the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are all slot levels used for indicating one of the following: configuring the configuration or the period of the blind detection time into each slot, and configuring the configuration or the period of the blind detection time into every other slots; the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are the same and all are mini-slot levels, wherein the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are all mini-slot levels used for indicating one of the following: the configuration or the period of the blind detection time is configured to be each mini-slot, and the configuration or the period of the blind detection time is configured to be every other plurality of mini-slots; the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are the same and are all OFDM symbol levels, wherein the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are all OFDM symbol levels for indicating one of the following: the configuration or period of the blind detection time is configured to be every OFDM symbol, and the configuration or period of the blind detection time is configured to be every other OFDM symbol; the blind detection time configuration or the periodic configuration of the plurality of second resource sets needs to satisfy an inclusion relationship, wherein the inclusion relationship is as follows: the blind detection time or period configuration of the first resource set is a subset of the blind detection time or period configuration of the second resource set; the blind detection time configurations or the periodic configurations of the plurality of second resource sets occur within a fixed time unit the same number of times, wherein the fixed time unit comprises one of: the method comprises the steps of a wireless frame, a subframe, a slot, a PDCCH region of the slot and a plurality of OFDM symbols with fixed number and fixed positions of the slot.

Optionally, the dynamic signaling indication is a multiplexing or rate matching dynamic signaling indication for a first set of resources, wherein a valid time domain range of the multiplexing or rate matching dynamic signaling indication for the first set of resources is determined to be at least one of: the first resource set and the time-frequency resource corresponding to the first blind detection time or the first periodic configuration time of the resource used by the PDSCH transmission are overlapped; time-frequency resources corresponding to all blind detection moments or all periodic configuration moments when the first resource set overlaps with resources used for PDSCH transmission; the first resource set and resources used by the PDSCH transmission are time-frequency resources corresponding to all blind detection moments or all periodic configuration moments when a PDCCH region is overlapped; determining an effective time domain range according to a blind detection result of the second communication node on a time-frequency resource where the first resource set and a resource used for the PDSCH transmission are overlapped; a first subframe or a first slot in which the first set of resources overlaps with resources for PDSCH transmission; the first set of resources is all subframes or all slots that overlap with resources for PDSCH transmission.

Optionally, the PDCCH region is allowed to be in one of the following levels: subframe level, slot level, mini-slot level, OFDM symbol level; when the PDCCH is in a subframe level, the PDCCH regions are first OFDM symbols of the subframe; when the PDCCH is in a slot level, the PDCCH regions are the first OFDM symbols of the slot; when the PDCCH is in a mini-slot level, the PDCCH region is a plurality of first OFDM symbols of the mini-slot or a plurality of OFDM symbols of a fixed position of the slot; when the PDCCH region is at OFDM symbol level, the PDCCH region is OFDM symbol of a preset fixed position.

Optionally, the transmission module sends a dynamic indication for activating or deactivating the dynamic signaling indication to the second communication node.

Optionally, the first determining module determines the following information about the first set of resources for the second communication node: a dynamic signaling indication for indicating whether the first set of resources is multiplexed for PDSCH transmission or whether PDSCH transmission is required to perform rate matching; after the above steps are performed, the transmission module sends one or more dynamic signaling indications to the second communication node for one or a group of the first resource sets.

Optionally, part or all of the bits of the dynamic signaling indication allow to indicate at least one of the following meanings: the part or all of the bits are used for indicating at least one of the following information of the first resource set corresponding to the adjacent bits or bit groups: multiplexing/rate matching after time domain splitting, multiplexing/rate matching after frequency domain splitting, and multiplexing/rate matching after space domain splitting; the part or all of the bits are used to indicate at least one of the following information for a particular first set of resources: multiplexing/rate matching after time domain splitting, multiplexing/rate matching after frequency domain splitting, and multiplexing/rate matching after space domain splitting; wherein the particular first set of resources is allowed to be one of: the first resource set which needs blind detection by the second communication node is used for scheduling the first resource set where the PDCCH transmitted by the PDSCH is located, the dynamic signaling indicates the sent first resource set, and the first determining module semi-statically configures the specific first resource set; the part or all of the bits are used for indicating one of the following information of all the first resource sets corresponding to all the remaining bits or bit groups: multiplexing/rate matching after time domain splitting, multiplexing/rate matching after frequency domain splitting, and multiplexing/rate matching after space domain splitting; the part or all of the bits are used for indicating whether the following conditions occur in the following time unit: activation of a carrier and/or bandwidth part, deactivation of a carrier and/or bandwidth part, and switching of a carrier and/or bandwidth part; the part or all of the bits are used for indicating whether the length of the dynamic signaling indication sent by the subsequent time unit is changed.

Optionally, the splitting comprises: dividing at least one of the time domain, the frequency domain and the space domain of the first resource set equally; wherein, n is determined according to the number of redundant bits and is divided into n equal parts, and n is a positive integer; after the equally dividing processing is executed, the non-redundant bit and the redundant bit jointly indicate which equally divided parts of the first resource set can be multiplexed by the PDSCH transmission, or the PDSCH does not need to execute rate matching on which equally divided parts; wherein the redundant bits are the partial or all bits.

According to another embodiment of the present invention, there is also provided an apparatus for determining time-frequency resources, which is applied to a second communication node, and includes:

a receiving module, configured to receive information regarding a first set of resources transmitted by a first communication node, wherein the information includes at least one of: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed for PDSCH or PUSCH transmission, or dynamic signaling indication for performing rate matching is required for PDSCH or PUSCH transmission;

a second determining module, configured to determine one of the following configuration information according to the information: allowing time frequency resources multiplexed for PDSCH transmission, wherein the PDSCH transmission comprises a process of transmitting data through the PDSCH, and the time frequency resources do not need to perform rate matching during the PDSCH transmission; the PUSCH transmission includes a process of transmitting data to a first communication node over a PUSCH.

It should be added that, in the first embodiment, the method embodiment performed by the second communication node may be performed by the apparatus applied to the second communication node.

Optionally, the first set of resources is one of the following information: one or more, full or partial Resource sets; one or more, whole or partial CORESET; one or more specific signals or specific channel resources, wherein the specific signals or specific channel resources comprise one of: reference signal resources, synchronization signal resources, broadcast channel resources.

Optionally, the dynamic signaling indication is a multiplexing or rate matching dynamic signaling indication for a first set of resources, wherein a valid time domain range of the multiplexing or rate matching dynamic signaling indication for the first set of resources is determined to be at least one of: the first resource set and the time-frequency resource corresponding to the first blind detection time or the first periodic configuration time of the resource used by the PDSCH transmission are overlapped; time-frequency resources corresponding to all blind detection moments or all periodic configuration moments when the first resource set overlaps with resources used for PDSCH transmission; the first resource set and resources used by the PDSCH transmission are time-frequency resources corresponding to all blind detection moments or all periodic configuration moments when a PDCCH region is overlapped;

determining an effective time domain range according to a blind detection result of the second determining module on the time-frequency resource where the first resource set and the resource used for the PDSCH transmission are overlapped; a first subframe or a first slot in which the first set of resources overlaps with resources for PDSCH transmission; the first set of resources is all subframes or all slots that overlap with resources for PDSCH transmission.

Optionally, the second determining module performs blind detection, where when the blind detection result of the second determining module is that the PDCCH sent to the second determining module is detected, the method further includes: the second determining module performs rate matching on the detected time-frequency resources occupied by the PDCCH sent to the second determining module, and determines that the multiplexing or rate matching dynamic signaling indication is valid for the following time for the rest of resources except the time-frequency resources occupied by the PDCCH sent to the second determining module: the blind detection time and the first resource set are overlapped with the resources used by the PDSCH transmission; or, the second determining module determines that the multiplexing or rate matching dynamic signaling indication is invalid for the first set of resources at the blind detection time; and at the blind detection time, forbidding all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission from being multiplexed for the PDSCH transmission, or performing rate matching on all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission at the blind detection time by the PDSCH transmission.

Optionally, the second determining module performs blind detection, where when the blind detection result of the second determining module is that the PDCCH sent to the second determining module is not detected, the method further includes: the multiplexing or rate matching dynamic signaling indication is valid for the first set of resources at the time of blind detection; or the multiplexing or rate matching dynamic signaling indicates that the first resource set is invalid at the blind detection time; and all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission in the first resource set at the blind detection time are allowed to be multiplexed for PDSCH transmission, or the PDSCH transmission does not need to perform rate matching on all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission at the blind detection time.

It should be noted that, the above modules may be implemented by software or hardware, and for the latter, the following may be implemented, but not limited to: the modules are all positioned in the same processor; alternatively, the modules are respectively located in different processors in any combination.

EXAMPLE III

According to another embodiment of the present invention, there is also provided a base station including:

a first processor for determining at least one of the following information regarding the first set of resources for the second communication node: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed for PDSCH or PUSCH transmission, or dynamic signaling indication for performing rate matching is required for PDSCH or PUSCH transmission;

first communication means for transmitting the information to the second communication node, wherein the PDSCH transmission comprises a process of transmitting data to the second communication node over a PDSCH; the PUSCH transmission includes a process by which the second communication node transmits data to the first communication node over a PUSCH.

It should be added that, in the first or second embodiments, the embodiments that can be performed by the first communication node can be performed by the base station.

According to another embodiment of the present invention, there is also provided a terminal including:

second communication means for receiving information regarding the first set of resources transmitted by the first communication node, wherein the information comprises at least one of: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed for PDSCH or PUSCH transmission, or dynamic signaling indication for performing rate matching is required for PDSCH or PUSCH transmission;

a second processor for determining one of the following configuration information based on the information: allowing time frequency resources multiplexed for PDSCH transmission, wherein the PDSCH transmission comprises a process of transmitting data through the PDSCH, and the time frequency resources do not need to perform rate matching during the PDSCH transmission; the PUSCH transmission comprises the process of transmitting data through a PUSCH.

It should be added that, in the first or second embodiments, the embodiments that can be performed by the second communication node can be performed by the terminal.

Example four

EXAMPLE five

It will be apparent to those skilled in the art that the modules or steps of the present invention described above may be implemented by a general purpose computing device, they may be centralized on a single computing device or distributed across a network of multiple computing devices, and alternatively, they may be implemented by program code executable by a computing device, such that they may be stored in a storage device and executed by a computing device, and in some cases, the steps shown or described may be performed in an order different than that described herein, or they may be separately fabricated into individual integrated circuit modules, or multiple ones of them may be fabricated into a single integrated circuit module. Thus, the present invention is not limited to any specific combination of hardware and software.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A method for determining time-frequency resources, comprising:

the first communication node determines at least one of the following information about the first set of resources for the second communication node: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed to Physical Downlink Shared Channel (PDSCH) or Physical Uplink Shared Channel (PUSCH) transmission, or whether dynamic signaling indication for performing rate matching is required to perform PDSCH or PUSCH transmission;

transmitting the information to the second communication node, wherein the PDSCH transmission comprises a process in which the first communication node transmits data to the second communication node over a PDSCH; the PUSCH transmission includes a process by which the second communication node transmits data to the first communication node over a PUSCH.

2. The method of claim 1, wherein the first set of resources is one of:

one or more, complete or partial, Resource sets or uplink control channel resources or uplink reserved resources;

one or more, complete or partial, control resource sets, CORESET or uplink control channel resources or uplink reserved resources;

one or more specific signals or specific channel resources, wherein the specific signals or specific channel resources comprise one or more of: reference signal time domain resources, reference signal frequency domain resources, synchronization signal time domain resources, synchronization signal frequency domain resources, broadcast channel time domain resources, broadcast channel frequency domain resources.

3. The method of claim 1, wherein the second set of resources comprises one of:

one or more, complete or partial, CORESET or uplink control channel resources or uplink reserved resources;

4. The method of claim 1, wherein:

the first communication node configuring one or more of said first set of resources for a second communication node;

and the configured time frequency resource parts of the plurality of first resource sets are forbidden to partially overlap or forbidden to completely overlap.

5. The method of claim 1, wherein:

when the first communication node configures a plurality of first resource sets for the second communication node, configuring priorities for part or all of the plurality of first resource sets.

6. The method of claim 5, wherein when the time-frequency resources of a plurality of the first resource sets overlap, determining whether the overlapping time-frequency resources are allowed to be multiplexed for PDSCH or PUSCH transmission, or whether the PDSCH or PUSCH transmission needs to perform rate matching on the overlapping time-frequency resources by:

and determining according to the dynamic signaling indication of the first resource set with higher priority.

7. The method of claim 1, wherein the first set of resources for the second communication node comprises one of:

part of time domain resources of the time domain resource unit are the first resource set;

a portion of the frequency domain resources within a frequency domain resource unit are the first set of resources.

8. The method of claim 1, wherein the first set of resources for the second communication node comprises at least one of:

in the time domain, periodically configuring a part of time domain resources of a time domain resource unit as the first resource set;

the time domain resource unit offset;

in the frequency domain, assigning a part of frequency domain resources in a frequency domain resource unit in the range of subcarriers as the first resource set;

in the frequency domain, a portion of the frequency domain resources within frequency domain resource units within a bandwidth range are designated as the first set of resources.

9. The method of claim 1, wherein when overlapping occurs in time-frequency resources of a plurality of the first resource sets, determining whether overlapping portions of the time-frequency resources are allowed to be multiplexed for PDSCH or PUSCH transmission, or whether PDSCH or PUSCH transmission requires rate matching of the overlapping portions of the time-frequency resources by:

performing an AND operation or an OR operation on the dynamic signaling indications of all of the overlapping plurality of first resource sets;

depending on the result of the AND operation or OR operation.

10. The method of claim 9, wherein the following information is agreed: the dynamic signaling indication is appointed to be set to be 1, which indicates that the corresponding first resource set allows all or part of the resources to be multiplexed for PDSCH or PUSCH transmission, or the PDSCH or PUSCH transmission does not need to perform rate matching on all or part of the resources of the corresponding first resource set; setting '0' to indicate that the corresponding first resource set is prohibited to be partially or completely multiplexed to PDSCH or PUSCH transmission, or the PDSCH or PUSCH transmission needs to perform rate matching on all or part of resources of the corresponding first resource set;

the dynamic signaling indication of all the overlapped multiple first resource sets is subjected to AND operation or OR operation, and the AND operation or OR operation is determined according to the result of the AND operation or OR operation, and comprises the following steps:

performing an OR operation on the dynamic signaling indication of the plurality of overlapping first resource sets;

and determining whether the overlapped part of the time frequency resources are allowed to be multiplexed for the PDSCH or PUSCH transmission or determining whether the PDSCH or PUSCH transmission needs to carry out rate matching on the overlapped part of the time frequency resources according to the result of the OR operation.

11. The method of claim 9, wherein in a case that the dynamic signaling indication is agreed to set "1" to indicate that the corresponding first resource set is prohibited from being partially or fully multiplexed for PDSCH or PUSCH transmission, or that the PDSCH or PUSCH transmission needs to perform rate matching on all or part of time-frequency resources of the corresponding first resource set, and set "0" to indicate that the corresponding first resource set is allowed to be fully or partially multiplexed for PDSCH or PUSCH transmission, or that the PDSCH or PUSCH transmission does not need to perform rate matching on all or part of time-frequency resources of the first resource set, the method further comprises:

performing an AND operation on the dynamic signaling indication of the plurality of overlapping first resource sets;

and determining whether the overlapped part of the time frequency resources is allowed to be multiplexed to the PDSCH or PUSCH transmission or whether the PDSCH or PUSCH transmission needs to perform rate matching on the overlapped part of the time frequency resources according to the result of the AND operation.

12. The method according to claim 1, wherein when overlapping time-frequency resources of a plurality of said first resource sets occurs, the following information is determined in different ways for different types of said first resource sets: information on whether overlapping portions of time-frequency resources are allowed to be multiplexed for the PDSCH or PUSCH transmission, or whether the PDSCH or PUSCH transmission requires rate matching of overlapping portions of time-frequency resources;

wherein the first set of resources of different types comprises one of: different time frequency resource allocation modes; the time frequency resource allocation ranges are different; the time frequency resource allocation granularity is different; the time frequency resources have different priorities.

13. The method according to claim 1, wherein when the first set of resources includes a plurality of the second sets of resources or is equivalent to a plurality of the second sets of resources, a plurality of the second sets of resources included in the same first set of resources need to satisfy at least one of the following characteristics:

the second communication nodes in the plurality of second resource sets have the same blind detection time configuration or periodic configuration;

the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are the same and are all slot levels, wherein the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are all slot levels used for indicating one of the following: configuring the configuration or the period of the blind detection time into each slot, and configuring the configuration or the period of the blind detection time into every other slots;

the blind detection time configuration or the periodic configuration levels of the plurality of second resource sets are the same and are all mini-slot levels, wherein the blind detection time configuration or the periodic configuration levels of the plurality of second resource sets are all mini-slot levels used for indicating one of the following: the configuration or the period of the blind detection time is configured to be each mini-slot, and the configuration or the period of the blind detection time is configured to be every other plurality of mini-slots;

the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are the same and are all orthogonal frequency division multiplexing symbol OFDM symbol levels, wherein the blind detection time configurations or the periodic configuration levels of the plurality of second resource sets are all orthogonal frequency division multiplexing symbol OFDM symbol levels used for indicating one of the following: the configuration or period of the blind detection time is configured to be every OFDM symbol, and the configuration or period of the blind detection time is configured to be every other OFDM symbol;

the blind detection time configuration or the periodic configuration of the plurality of second resource sets needs to satisfy an inclusion relationship, wherein the inclusion relationship is as follows: the blind detection time or the period configuration of the first resource set is a subset of the blind detection time or the period configuration of the second resource set;

the blind detection time configurations or the periodic configurations of the plurality of second resource sets occur within a fixed time unit the same number of times, wherein the fixed time unit comprises one of: the method comprises the steps of obtaining a plurality of OFDM symbols with a fixed number and a fixed position in one slot, wherein each OFDM symbol comprises a wireless frame, one subframe, one slot, a PDCCH (physical downlink control channel) domain or an uplink control channel range of the one slot.

14. The method of claim 1, wherein the dynamic signaling indication is a multiplexing or rate matching dynamic signaling indication for a first set of resources, and wherein a valid time domain range of the multiplexing or rate matching dynamic signaling indication for the first set of resources is determined to be at least one of:

the first resource set overlaps with resources used by the PDSCH or PUSCH transmission, and time-frequency resources corresponding to a first blind detection time or a first periodic configuration time;

the first resource set overlaps with resources used by the PDSCH or PUSCH transmission, and all blind detection time or all time-frequency resources corresponding to the periodic configuration time;

the first resource set and resources used for PDSCH or PUSCH transmission correspond to time-frequency resources at all blind detection moments or all periodic configuration moments when a PDCCH region or an uplink control channel resource range is overlapped;

determining an effective time domain range according to a blind detection result of the second communication node on a time-frequency resource where the first resource set is overlapped with a resource used for the PDSCH or PUSCH transmission;

a first subframe or a first slot in which the first set of resources overlaps with resources of a PDSCH or PUSCH transmission;

the first set of resources is all subframes or all slots that overlap with resources of a PDSCH or PUSCH transmission.

15. The method of claim 14, wherein the PDCCH region or uplink control channel resource range is allowed to be in one of the following levels: subframe level, slot level, mini-slot level, OFDM symbol level;

when the resource range is in a subframe level, the PDCCH region or the uplink control channel resource range is the first OFDM symbols of the subframe;

when the resource range is a slot level, the PDCCH region or the uplink control channel resource range is the first OFDM symbols of the slot;

when the resource range is in a mini-slot level, the PDCCH region or the uplink control channel resource range is a plurality of first OFDM symbols of the mini-slot or a plurality of fixed OFDM symbols of the slot;

when the OFDM symbol level is adopted, the PDCCH region or the uplink control channel resource range is an OFDM symbol with a preset fixed position.

16. The method according to claim 14, wherein when the second communication node detects the PDCCH sent to itself as the blind detection result, the method further comprises:

the second communication node performs rate matching on the detected time-frequency resources occupied by the PDCCH sent to the second communication node, and the multiplexing or rate matching dynamic signaling indication is effective for the following time for the rest of resources except the time-frequency resources occupied by the PDCCH sent to the second communication node: at the blind detection time, the first set of resources is on resources that overlap with resources used for the PDSCH transmission; or

The multiplexed or rate-matched dynamic signaling indicates invalidity to the first set of resources at the time of the blind detection; and at the blind detection time, forbidding all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission in the first resource set to be multiplexed for the PDSCH transmission, or at the blind detection time, performing rate matching on all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission in the first resource set.

17. The method of claim 14, wherein when the second communication node does not detect the PDCCH sent to itself as a blind detection result, the method further comprises:

the multiplexing or rate matching dynamic signaling indication is valid for the first set of resources at the time of blind detection; or

The multiplexing or rate matching dynamic signaling indicates that the first set of resources is invalid at the time of blind detection; and all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission in the first resource set at the blind detection time are allowed to be multiplexed for PDSCH transmission, or the PDSCH transmission does not need to perform rate matching on all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission at the blind detection time.

18. The method of claim 1, further comprising:

the first communication node sends a dynamic indication for activating or deactivating the dynamic signaling indication to the second communication node.

19. The method of claim 1, wherein the first communication node determines the following information about the first set of resources for the second communication node: a dynamic signaling indication for indicating whether the first set of resources is multiplexed for PDSCH or PUSCH transmission or whether PDSCH or PUSCH transmission is required to perform rate matching;

after performing the above steps, the first communication node sends one or more of the dynamic signaling indications to the second communication node for one or a group of the first set of resources.

20. The method of claim 1, further comprising:

determining a first set of resources corresponding to the dynamic signaling indication by one of: semi-static configuration mode, dynamic determination mode;

wherein the dynamic signaling indicates that different first resource sets are allowed to correspond to different time units, or different numbers of first resource sets are allowed to correspond to different time units; wherein the time cell comprises one of: slot, mini-slot, OFDM symbol, subframe.

21. The method of claim 1, wherein some or all bits of the dynamic signaling indication allow indicating at least one of the following meanings:

the part or all of the bits are used for indicating at least one of the following information of the first resource set corresponding to the adjacent bits or bit groups: multiplexing/rate matching after time domain splitting, multiplexing/rate matching after frequency domain splitting, and multiplexing/rate matching after space domain splitting;

the part or all of the bits are used to indicate at least one of the following information for a particular first set of resources: multiplexing/rate matching after time domain splitting, multiplexing/rate matching after frequency domain splitting, and multiplexing/rate matching after space domain splitting; wherein the particular first set of resources is allowed to be one of: the first resource set which needs blind detection by the second communication node is used for scheduling the first resource set where the PDCCH transmitted by the PDSCH is located, the dynamic signaling indicates the sent first resource set, and the first communication node is configured with a specific first resource set in a semi-static state;

the part or all of the bits are used for indicating one of the following information of all the first resource sets corresponding to all the remaining bits or bit groups: multiplexing/rate matching after time domain splitting, multiplexing/rate matching after frequency domain splitting, and multiplexing/rate matching after space domain splitting;

the part or all of the bits are used for indicating whether at least one of the following conditions occurs in the following time unit: activation of a carrier and/or bandwidth portion; deactivation of the carrier and/or bandwidth portions; a switch of carrier and/or bandwidth parts;

the part or all of the bits are used for indicating whether the length of the dynamic signaling indication sent by the subsequent time unit is changed.

22. The method of claim 21, wherein the splitting comprises:

dividing at least one of the time domain, the frequency domain and the space domain of the first resource set equally; wherein, n is determined according to the number of redundant bits and is divided into n equal parts, and n is a positive integer;

after the above-mentioned halving process is executed, the non-redundant bit and the redundant bit jointly indicate which halved parts of the first resource set can be multiplexed by the PDSCH or PUSCH transmission, or the PDSCH or PUSCH does not need to execute rate matching on which halved parts; wherein the redundant bits are the partial or all bits.

23. A method for determining time-frequency resources, comprising:

the second communication node receives information about the first set of resources transmitted by the first communication node, wherein the information comprises at least one of: time-frequency resources of a second resource set contained in the first resource set, configuration information of the second resource set contained in the first resource set, and time-frequency resource configuration information of the first resource set are used for indicating whether the first resource set is multiplexed for PDSCH or PUSCH transmission, or dynamic signaling indication for performing rate matching is required for PDSCH or PUSCH transmission;

determining one of the following configuration information according to the information: allowing time frequency resources multiplexed for PDSCH or PUSCH transmission, the PDSCH or PUSCH transmission not requiring rate matching, wherein the PDSCH transmission comprises a process of transmitting data to the second communication node through the PDSCH; the PUSCH transmission includes a process by which the second communication node transmits data to the first communication node over a PUSCH.

24. The method of claim 23, wherein the first set of resources is one of the following information:

one or more specific signals or specific channel resources, wherein the specific signals or specific channel resources comprise one of: reference signal resources, synchronization signal resources, broadcast channel resources.

25. The method of claim 23, wherein the second set of resources comprises one of:

26. The method of claim 23, wherein the dynamic signaling indication is a multiplexing or rate matching dynamic signaling indication for a first set of resources, and wherein a valid time domain range of the multiplexing or rate matching dynamic signaling indication for the first set of resources is determined to be at least one of:

time-frequency resources corresponding to a first blind detection time or a first periodic configuration time at which the first resource set overlaps with resources used for the PDSCH or PUSCH transmission;

time-frequency resources corresponding to all blind detection moments or all periodic configuration moments when the first resource set overlaps with resources used for the PDSCH or PUSCH transmission;

27. The method of claim 26, wherein the second communication node performs blind detection, and wherein when the second communication node detects the PDCCH sent to itself as a blind detection result, the method further comprises:

the second communication node performs rate matching on the detected time-frequency resources occupied by the PDCCH sent to the second communication node, and determines that the multiplexing or rate matching dynamic signaling indication is valid for the following time for the rest of resources except the time-frequency resources occupied by the PDCCH sent to the second communication node: the blind detection time and the first resource set are overlapped with the resources used by the PDSCH transmission; or

The second communications node determining that the multiplexing or rate matching dynamic signaling indication is invalid for the first set of resources at the time of the blind detection; and at the blind detection time, forbidding all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission from being multiplexed for the PDSCH transmission, or performing rate matching on all or part of the time-frequency resources overlapped with the resources used by the PDSCH transmission at the blind detection time by the PDSCH transmission.

28. The method of claim 26, wherein the second communication node performs blind detection, and wherein when the second communication node does not detect the PDCCH intended for itself as a result of the blind detection, the method further comprises:

29. The method according to claim 7 or 8,

the time domain resource unit or the frequency domain resource unit is configured by one of the following modes:

the system is pre-configured, the first communication node is semi-statically configured, and the first communication node is dynamically configured.

30. An apparatus for determining time-frequency resources, comprising:

a transmission module configured to transmit the information to the second communication node, wherein the PDSCH transmission comprises a process of transmitting data to the second communication node via PDSCH; the PUSCH transmission includes a process by which the second communication node transmits data to the first communication node over a PUSCH.

31. An apparatus for determining time-frequency resources, comprising:

a second determining module, configured to determine one of the following configuration information according to the information: allowing time frequency resources multiplexed for PDSCH transmission, wherein the PDSCH transmission comprises a process of transmitting data through the PDSCH, and the time frequency resources do not need to perform rate matching during the PDSCH transmission; the PUSCH transmission includes a process of transmitting data over a PUSCH.

32. A base station, comprising:

first communication means for transmitting the information to the second communication node, wherein the PDSCH transmission comprises a process of transmitting data to the second communication node over a PDSCH; the PUSCH transmission includes a process of transmitting data over a PUSCH.

33. A terminal, comprising:

34. A storage medium, comprising a stored program, wherein the program when executed performs the method of any one of claims 1 to 29.

35. A processor, characterized in that the processor is configured to run a program, wherein the program when running performs the method of any of the preceding claims 1 to 29.